diff --git a/anasen_analysis_vignesh/.vscode/c_cpp_properties.json b/anasen_analysis_vignesh/.vscode/c_cpp_properties.json new file mode 100644 index 0000000..744c2d6 --- /dev/null +++ b/anasen_analysis_vignesh/.vscode/c_cpp_properties.json @@ -0,0 +1,84 @@ +{ + "configurations": [ + { + "name": "Hades", + "includePath": [ + "${workspaceFolder}/**", + "/usr/include/x86_64-linux-gnu/qt6/**", + "/usr/local/cern/root_v6.26.06/include/**" + ], + "defines": [], + "compilerPath": "/usr/bin/gcc", + "cStandard": "c17", + "cppStandard": "gnu++17", + "intelliSenseMode": "linux-gcc-x64" + }, + { + "name": "RyanUbuntu", + "includePath": [ + "${workspaceFolder}/**", + "/usr/include/x86_64-linux-gnu/qt6/**", + "/opt/root/include/**" + ], + "defines": [], + "compilerPath": "/usr/bin/gcc", + "cStandard": "c17", + "cppStandard": "gnu++17", + "intelliSenseMode": "linux-gcc-x64" + }, + { + "name": "Anasen", + "includePath": [ + "${workspaceFolder}/**", + "/usr/include/x86_64-linux-gnu/qt6/**", + "/opt/root/include/**" + ], + "defines": [], + "compilerPath": "/usr/bin/gcc", + "cStandard": "c17", + "cppStandard": "gnu++17", + "intelliSenseMode": "linux-gcc-x64" + }, + { + "name": "Splitpole", + "includePath": [ + "${workspaceFolder}/**", + "/usr/include/x86_64-linux-gnu/qt6/**", + "/home/splitpole/cern/root/include/**", + "/usr/include/x86_64-linux-gnu/qt6/QtWidgets", + "/usr/include/x86_64-linux-gnu/qt6/QtCore" + ], + "defines": [], + "compilerPath": "/usr/bin/gcc", + "cStandard": "c17", + "cppStandard": "gnu++17", + "intelliSenseMode": "linux-gcc-x64" + }, + { + "name": "Penguin", + "includePath": [ + "${workspaceFolder}/**", + "/usr/include/x86_64-linux-gnu/qt6/**", + "/usr/local/cern/root/include/**" + ], + "defines": [], + "compilerPath": "/usr/bin/gcc", + "cStandard": "c17", + "cppStandard": "gnu++17", + "intelliSenseMode": "linux-gcc-x64" + }, + { + "name": "VigneshROG", + "includePath": [ + "${workspaceFolder}/**", + "/home/vsitaraman/root/include/**" + ], + "defines": [], + "compilerPath": "/usr/bin/gcc", + "cStandard": "c17", + "cppStandard": "gnu++17", + "intelliSenseMode": "linux-gcc-x64" + } + ], + "version": 4 +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/.vscode/settings.json b/anasen_analysis_vignesh/.vscode/settings.json new file mode 100644 index 0000000..1c692d7 --- /dev/null +++ b/anasen_analysis_vignesh/.vscode/settings.json @@ -0,0 +1,130 @@ +{ + "files.associations": { + "ryanScript.C": "cpp", + "ryanSelector.C": "cpp", + "array": "cpp", + "deque": "cpp", + "list": "cpp", + "string": "cpp", + "unordered_map": "cpp", + "unordered_set": "cpp", + "vector": "cpp", + "string_view": "cpp", + "initializer_list": "cpp", + "span": "cpp", + "ApplyMapping.C": "cpp", + "script.C": "cpp", + "Analyzer.C": "cpp", + "PreAnalysis.C": "cpp", + "ANASEN_model.C": "cpp", + "algorithm": "cpp", + "allocator": "cpp", + "limits": "cpp", + "atomic": "cpp", + "bit": "cpp", + "*.tcc": "cpp", + "cctype": "cpp", + "chrono": "cpp", + "clocale": "cpp", + "cmath": "cpp", + "codecvt": "cpp", + "compare": "cpp", + "complex": "cpp", + "concepts": "cpp", + "condition_variable": "cpp", + "cstdarg": "cpp", + "cstddef": "cpp", + "cstdint": "cpp", + "cstdio": "cpp", + "cstdlib": "cpp", + "cstring": "cpp", + "ctime": "cpp", + "cwchar": "cpp", + "cwctype": "cpp", + "map": "cpp", + "set": "cpp", + "exception": "cpp", + "functional": "cpp", + "iterator": "cpp", + "memory": "cpp", + "memory_resource": "cpp", + "numeric": "cpp", + "optional": "cpp", + "random": "cpp", + "ratio": "cpp", + "source_location": "cpp", + "system_error": "cpp", + "tuple": "cpp", + "type_traits": "cpp", + "utility": "cpp", + "fstream": "cpp", + "future": "cpp", + "iomanip": "cpp", + "iosfwd": "cpp", + "iostream": "cpp", + "istream": "cpp", + "mutex": "cpp", + "new": "cpp", + "numbers": "cpp", + "ostream": "cpp", + "semaphore": "cpp", + "sstream": "cpp", + "stdexcept": "cpp", + "stop_token": "cpp", + "streambuf": "cpp", + "thread": "cpp", + "cinttypes": "cpp", + "typeinfo": "cpp", + "variant": "cpp", + "bitset": "cpp", + "forward_list": "cpp", + "anasenMS.C": "cpp", + "*.icc": "cpp", + "any": "cpp", + "cfenv": "cpp", + "csignal": "cpp", + "regex": "cpp", + "scoped_allocator": "cpp", + "shared_mutex": "cpp", + "valarray": "cpp", + "processRun.C": "cpp", + "TrackRecon.C": "cpp", + "processRuns.C": "cpp", + "Analysis.C": "cpp", + "datastructs.h": "c", + "ANASENPlotEdit.C": "cpp", + "GetMean_Q3_new.C": "cpp", + "AlphaCal_new.C": "cpp", + "f1.C": "cpp", + "GeoCal_Maria_new.C": "cpp", + "PCPulser_All_new.C": "cpp", + "PosCal_2.C": "cpp", + "AutoFit.C": "cpp", + "Fitting.C": "cpp", + "PCGainMatch.C": "cpp", + "Analyzer1.C": "cpp", + "FitHistogramsWithTSpectrum_Sequential_Improved.C": "cpp", + "PlotAndFitCentroids.C": "cpp", + "MatchAndPlotCentroids.C": "cpp", + "GainMatch.C": "cpp", + "GainMatchSX3.C": "cpp", + "RelBack_Fix_new.C": "cpp", + "SiRelativeGains_Step1_new.C": "cpp", + "charconv": "cpp", + "format": "cpp", + "GainMatchSX3Front.C": "cpp", + "GainMatchSX3Front1.C": "cpp", + "Calibration.C": "cpp", + "GainMatchQQQ.C": "cpp", + "UTF-8gainmatch.C": "cpp", + "MakePlotsQQQ.C": "cpp", + "MakePlotsSX3.C": "cpp", + "QQQ_Calibcheck.C": "cpp", + "QQQ_Calcheck.C": "cpp", + "makeplots.C": "cpp", + "GlobalMinimizeQQQ.C": "cpp", + "QQQStage2.C": "cpp", + "inspect.C": "cpp" + }, + "github-enterprise.uri": "https://fsunuc.physics.fsu.edu" +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/27Al b/anasen_analysis_vignesh/27Al new file mode 100644 index 0000000..cb1df44 Binary files /dev/null and b/anasen_analysis_vignesh/27Al differ diff --git a/anasen_analysis_vignesh/Analysis.C b/anasen_analysis_vignesh/Analysis.C new file mode 100644 index 0000000..d646366 --- /dev/null +++ b/anasen_analysis_vignesh/Analysis.C @@ -0,0 +1,20 @@ +#include "TChain.h" +#include + + + +void Analysis(int start, int end) { + // Create a TChain + TChain *chain = new TChain("tree"); + for(int i = start; i < end+1; i++) { + chain->Add(Form("data/root_data/Run_%03d_mapped.root", i)); + } + + // Process the chain using Analyzer.C+ + chain->Process("Analyzer.C+"); +} + +// Define a macro with the same name as the script +void Analysis() { + Analysis(72, 194); // Adjust the range if needed +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/Analyzer.C b/anasen_analysis_vignesh/Analyzer.C new file mode 100644 index 0000000..f9eed6e --- /dev/null +++ b/anasen_analysis_vignesh/Analyzer.C @@ -0,0 +1,876 @@ +#define Analyzer_cxx + +#include "Analyzer.h" +#include "Armory/ClassSX3.h" +#include "Armory/ClassPW.h" + +#include +#include +#include +#include +#include "TVector3.h" + +#include +#include +#include +#include +#include +#include + +TH2F *hsx3IndexVE; +TH2F *hqqqIndexVE; +TH2F *hpcIndexVE; + +TH2F *hpcIndexVE_GM; +TH2F *hsx3Coin; +TH2F *hqqqCoin; +TH2F *hpcCoin; +TH2F *hAVCcoin; + +TH2F *hqqqPolar; +TH2F *hsx3VpcIndex; +TH2F *hqqqVpcIndex; +TH2F *hqqqVpcE; +TH2F *hsx3VpcE; +TH2F *hanVScatsum; +TH2F *hanVScatsum_a[24]; +TH1F *hPC_E[48]; +TH1F *hCat4An; +TH1F *hCat0An; +TH1F *hAnodehits; +TH2F *hNosvAe; + +int padID = 0; + +SX3 sx3_contr; +PW pw_contr; +PW pwinstance; +TVector3 hitPos; +// TVector3 anodeIntersection; +std::map> slopeInterceptMap; +// SX3 Calibration Arrays +const int MAX_DET = 24; +const int MAX_UP = 4; +const int MAX_DOWN = 4; +const int MAX_BK = 4; +double backGain[MAX_DET][MAX_BK] = {{0}}; +bool backGainValid[MAX_DET][MAX_BK] = {{false}}; +double frontGain[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{0}}}}; +bool frontGainValid[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{false}}}}; + +// QQQ Calibration Arrays +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; + +bool HitNonZero; +bool sx3ecut; +bool qqqEcut; + +TH1F *hZProj; +TH1F *hPCZProj; + +void Analyzer::Begin(TTree * /*tree*/) +{ + TString option = GetOption(); + + hsx3IndexVE = new TH2F("hsx3IndexVE", "SX3 index vs Energy; sx3 index ; Energy", 24 * 12, 0, 24 * 12, 400, 0, 5000); + hqqqIndexVE = new TH2F("hqqqIndexVE", "QQQ index vs Energy; QQQ index ; Energy", 4 * 2 * 16, 0, 4 * 2 * 16, 400, 0, 5000); + hpcIndexVE = new TH2F("hpcIndexVE", "PC index vs Energy; PC index ; Energy", 2 * 24, 0, 2 * 24, 400, 0, 16000); + hpcIndexVE_GM = new TH2F("hpcIndexVE_GM", "PC index vs Energy; PC index ; Energy", 2 * 24, 0, 2 * 24, 400, 0, 16000); + + hsx3Coin = new TH2F("hsx3Coin", "SX3 Coincident", 24 * 12, 0, 24 * 12, 24 * 12, 0, 24 * 12); + hqqqCoin = new TH2F("hqqqCoin", "QQQ Coincident", 4 * 2 * 16, 0, 4 * 2 * 16, 4 * 2 * 16, 0, 4 * 2 * 16); + hpcCoin = new TH2F("hpcCoin", "PC Coincident", 2 * 24, 0, 2 * 24, 2 * 24, 0, 2 * 24); + hAVCcoin = new TH2F("hAVCcoin", "Anode vs Cathode Coincident", 24, 0, 24, 24, 0, 24); + + hqqqPolar = new TH2F("hqqqPolar", "QQQ Polar ID", 16 * 4, -TMath::Pi(), TMath::Pi(), 16, 10, 50); + + hsx3VpcIndex = new TH2F("hsx3Vpcindex", "sx3 vs pc; sx3 index; pc index", 24 * 12, 0, 24 * 12, 48, 0, 48); + hqqqVpcIndex = new TH2F("hqqqVpcindex", "qqq vs pc; qqq index; pc index", 4 * 2 * 16, 0, 4 * 2 * 16, 48, 0, 48); + + hqqqVpcE = new TH2F("hqqqVpcEnergy", "qqq vs pc; qqq energy; pc energy", 400, 0, 5000, 800, 0, 16000); + + hsx3VpcE = new TH2F("hsx3VpcEnergy", "sx3 vs pc; sx3 energy; pc energy", 400, 0, 5000, 800, 0, 16000); + + hZProj = new TH1F("hZProj", "Z Projection", 1200, -600, 600); + hPCZProj = new TH1F("hPCZProj", "PC Z Projection", 600, -300, 300); + + hanVScatsum = new TH2F("hanVScatsum", "Anode vs Cathode Sum; Anode E; Cathode E", 400, 0, 16000, 400, 0, 20000); + hCat4An = new TH1F("hCat4An", "Number of Cathodes/Anode", 24, 0, 24); + hCat0An = new TH1F("hCat0An", "Number of Cathodes without Anode", 24, 0, 24); + hAnodehits = new TH1F("hAnodehits", "Number of Anode hits", 24, 0, 24); + hNosvAe = new TH2F("hnosvAe", "Number of Cathodes/Anode vs Anode Energy", 20, 0, 20, 400, 0, 16000); + // for (int i = 0; i < 24; i++) + // { + // TString histName = Form("hAnodeVsCathode_%d", i); + // TString histTitle = Form("Anode %d vs Cathode Sum; Anode E; Cathode Sum E", i); + // hanVScatsum_a[i] = new TH2F(histName, histTitle, 400, 0, 16000, 400, 0, 20000); + // } + // for (int i = 0; i < 48; i++) + // { + // TString histName = Form("hCathode_%d", i); + // TString histTitle = Form("Cathode_E_%d;", i); + // hPC_E[i] = new TH1F(histName, histTitle, 3200, 0, 32000); + // } + sx3_contr.ConstructGeo(); + pw_contr.ConstructGeo(); + + std::ifstream inputFile("slope_intercept_results.txt"); + + if (inputFile.is_open()) + { + std::string line; + int index; + double slope, intercept; + while (std::getline(inputFile, line)) + { + std::stringstream ss(line); + ss >> index >> slope >> intercept; + // wires 37, 39, 44 have fit data that is incorrect or not present, they have thus been set to 1,0 (slope, intercept) for convenience + // wire 19 the 4th point was genereated using the slope of the line produced uising the other 3 points from the wire 1 vs wire 19 plot + if (index >= 0 && index <= 47) + { + slopeInterceptMap[index] = std::make_pair(slope, intercept); + } + } + inputFile.close(); + } + else + { + std::cerr << "Error opening slope_intercept.txt" << std::endl; + } + + std::string filename = "sx3_GainMatchback.txt"; + + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + return; + } + + int id, bk; + double gain; + while (infile >> id >> bk >> gain) + { + backGain[id][bk] = gain; + if (backGain[id][bk] > 0) + backGainValid[id][bk] = true; + else + backGainValid[id][bk] = false; + } + + infile.close(); + std::cout << "Loaded back gains from " << filename << std::endl; + + std::string filename1 = "sx3_GainMatchfront.txt"; + + std::ifstream infile1(filename1); + if (!infile1.is_open()) + { + std::cerr << "Error opening " << filename1 << "!" << std::endl; + return; + } + + int idf, bkf, uf, df; + double fgain; + while (infile1 >> idf >> bkf >> uf >> df >> fgain) + { + frontGain[idf][bkf][uf][df] = fgain; + frontGainValid[idf][bkf][uf][df] = true; + } + + // QQQ Gain Matching and Calibration + // ----------------------- Load QQQ Gains + { + std::string filename = "qqq_GainMatch.txt"; + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + } + else + { + int det, ring, wedge; + double gainw, gainr; + while (infile >> det >> ring >> wedge >> gainw >> gainr) + { + qqqGain[det][ring][wedge] = gainw; + // qqqrGain[det][ring][wedge] = gainr; + qqqGainValid[det][ring][wedge] = (gainw > 0); + // qqqrGainValid[det][ring][wedge] = (gainr > 0); + } + infile.close(); + std::cout << "Loaded QQQ gains from " << filename << std::endl; + } + } + // ----------------------- Load QQQ Calibrations + { + std::string filename = "qqq_Calib.txt"; + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + } + else + { + int det, ring, wedge; + double slope; + while (infile >> det >> ring >> wedge >> slope) + { + qqqCalib[det][ring][wedge] = slope; + qqqCalibValid[det][ring][wedge] = (slope > 0); + } + infile.close(); + std::cout << "Loaded QQQ calibrations from " << filename << std::endl; + } + } +} + +Bool_t Analyzer::Process(Long64_t entry) +{ + + // if ( entry > 100 ) return kTRUE; + + hitPos.Clear(); + HitNonZero = false; + + // if( entry > 1) return kTRUE; + // printf("################### ev : %llu \n", entry); + + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + // sx3.Print(); + + // ########################################################### Raw data + // //======================= SX3 + sx3ecut = false; + std::vector> ID; // first = id, 2nd = index + for (int i = 0; i < sx3.multi; i++) + { + ID.push_back(std::pair(sx3.id[i], i)); + hsx3IndexVE->Fill(sx3.index[i], sx3.e[i]); + + if (sx3.e[i] > 100) + { + sx3ecut = true; + } + + for (int j = i + 1; j < sx3.multi; j++) + { + hsx3Coin->Fill(sx3.index[i], sx3.index[j]); + } + + for (int j = 0; j < pc.multi; j++) + { + if (pc.index[j] < 24 && pc.e[j] > 100) + { + hsx3VpcIndex->Fill(sx3.index[i], pc.index[j]); + // if( sx3.ch[index] > 8 ){ + // hsx3VpcE->Fill( sx3.e[i], pc.e[j] ); + // } + } + } + } + + if (ID.size() > 0) + { + std::sort(ID.begin(), ID.end(), [](const std::pair &a, const std::pair &b) + { return a.first < b.first; }); + // printf("##############################\n"); + // for( size_t i = 0; i < ID.size(); i++) printf("%zu | %d %d \n", i, ID[i].first, ID[i].second ); + + std::vector> sx3ID; + sx3ID.push_back(ID[0]); + bool found = false; + for (size_t i = 1; i < ID.size(); i++) + { + if (ID[i].first == sx3ID.back().first) + { + sx3ID.push_back(ID[i]); + if (sx3ID.size() >= 3) + { + found = true; + } + } + else + { + if (!found) + { + sx3ID.clear(); + sx3ID.push_back(ID[i]); + } + } + } + + // printf("---------- sx3ID Multi : %zu \n", sx3ID.size()); + + if (found) + { + int sx3ChUp, sx3ChDn, sx3ChBk; + float sx3EUp, sx3EDn; + // printf("------ sx3 ID : %d, multi: %zu\n", sx3ID[0].first, sx3ID.size()); + for (size_t i = 0; i < sx3ID.size(); i++) + { + int index = sx3ID[i].second; + // printf(" %zu | index %d | ch : %d, energy : %d \n", i, index, sx3.ch[index], sx3.e[index]); + + if (sx3.ch[index] < 8) + { + if (sx3.ch[index] % 2 == 0) + { + sx3ChDn = sx3.ch[index]; + sx3EDn = sx3.e[index]; + } + else + { + sx3ChUp = sx3.ch[index]; + sx3EUp = sx3.e[index]; + } + } + else + { + sx3ChBk = sx3.ch[index]; + } + for (int j = 0; j < pc.multi; j++) + { + // hsx3VpcIndex->Fill( sx3.index[i], pc.index[j] ); + if (sx3.ch[index] > 8) + { + hsx3VpcE->Fill(sx3.e[i], pc.e[j]); + // hpcIndexVE->Fill( pc.index[i], pc.e[i] ); + } + } + } + + // sx3_contr.CalSX3Pos(sx3ID[0].first, sx3ChUp, sx3ChDn, sx3ChBk, sx3EUp, sx3EDn); + // hitPos = sx3_contr.GetHitPos(); + // HitNonZero = true; + // hitPos.Print(); + } + } + + // //======================= QQQ + + qqqEcut = false; + for (int i = 0; i < qqq.multi; i++) + { + // for( int j = 0; j < pc.multi; j++){ + // if(pc.index[j]==4){ + hqqqIndexVE->Fill(qqq.index[i], qqq.e[i]); + // } + // printf("QQQ ID : %d, ch : %d, e : %d \n", qqq.id[i], qqq.ch[i], qqq.e[i]); + if (qqq.e[i] > 100) + { + qqqEcut = true; + } + // } + for (int j = 0; j < qqq.multi; j++) + { + if (j == i) + continue; + hqqqCoin->Fill(qqq.index[i], qqq.index[j]); + } + + for (int k = 0; k < pc.multi; k++) + { + if (pc.index[k] < 24 && pc.e[k] > 50) + { + hqqqVpcE->Fill(qqq.e[i], pc.e[k]); + // hpcIndexVE->Fill( pc.index[i], pc.e[i] ); + hqqqVpcIndex->Fill(qqq.index[i], pc.index[k]); + } + } + + // } + + for (int j = i + 1; j < qqq.multi; j++) + { + // if( qqq.used[i] == true ) continue; + + // if( qqq.id[i] == qqq.id[j] && (16 - qqq.ch[i]) * (16 - qqq.ch[j]) < 0 ){ // must be same detector and wedge and ring + if (qqq.id[i] == qqq.id[j]) + { // must be same detector + + if (qqq.e[i] > 100) + qqqEcut = true; + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + float eWedgeRaw = 0.0; + float eWedge = 0.0; + float eWedgeMeV = 0.0; + float eRingRaw = 0.0; + float eRing = 0.0; + float eRingMeV = 0.0; + // plug in gains + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && /*qqqrGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16] &&*/ qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedgeRaw = qqq.e[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + // printf("Wedge E: %.2f Gain: %.4f \n", eWedge, qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]); + chRing = qqq.ch[j] - 16; + eRingRaw = qqq.e[j]; + eRing = qqq.e[j]; //* qqqrGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i]-16]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 /* && qqqrGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16] */ && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + eWedgeRaw = qqq.e[j]; + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i]; // * qqqrGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + eRingRaw = qqq.e[i]; + } + else + continue; + // plug in calibrations + if (qqqCalibValid[qqq.id[i]][chRing][chWedge]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + } + else + continue; + + // printf(" ID : %d , chWedge : %d, chRing : %d \n", qqq.id[i], chWedge, chRing); + + double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + double rho = 50. + 40. / 16. * (chRing + 0.5); + // if(qqq.e[i]>50){ + hqqqPolar->Fill(theta, rho); + // } + // qqq.used[i] = true; + // qqq.used[j] = true; + + if (!HitNonZero) + { + double x = rho * TMath::Cos(theta); + double y = rho * TMath::Sin(theta); + hitPos.SetXYZ(x, y, 23 + 75 + 30); + HitNonZero = true; + } + } + } + } + } + // //======================= PC + + // Calculate the crossover points and put them into an array + + pwinstance.ConstructGeo(); + Coord Crossover[24][24][2]; + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha, beta; + int index = 0; + for (int i = 0; i < pwinstance.An.size(); i++) + { + a = pwinstance.An[i].first - pwinstance.An[i].second; + + for (int j = 0; j < pwinstance.Ca.size(); j++) + { + // Ok so this method uses what is essentially the solution of 2 equations to find the point of intersection between the anode and cathode wires + // here a and c are the vectors of the anode and cathode wires respectively + // diff is the perpendicular vector between the anode and cathode wires + // The idea behind this is to then find the scalars alpha and beta that give a ratio between 0 and -1, + + c = pwinstance.Ca[j].first - pwinstance.Ca[j].second; + diff = pwinstance.An[i].first - pwinstance.Ca[j].first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + beta = (a2 * cdiff - ac * adiff) / denom; + + Crossover[i][j][0].x = pwinstance.An[i].first.X() + alpha * a.X(); + Crossover[i][j][0].y = pwinstance.An[i].first.Y() + alpha * a.Y(); + Crossover[i][j][0].z = pwinstance.An[i].first.Z() + alpha * a.Z(); + if (Crossover[i][j][0].z < -190 || Crossover[i][j][0].z > 190) + { + Crossover[i][j][0].z = 9999999; + } + // placeholder variable Crossover[i][j][1].x has nothing to do with the geometry of the crossover and is being used to store the alpha value- + //-so that it can be used to sort "good" hits later + Crossover[i][j][1].x = alpha; + Crossover[i][j][1].y = 0; + // if(i==0){ + // printf("CID, Crossover z and alpha are : %d %f %f \n", j, Crossover[i][j][0].z, Crossover[i][j][1].x /*this is alpha*/); + // } + // } + // } + } + } + // printf("Anode and cathode indices, alpha, denom, andiff, cndiff : %d %d %f %f %f %f\n", i, j, alpha, denom, adiff, cdiff); + + // anodeIntersection.Clear(); + for (int i = 0; i < pc.multi; i++) + { + + if (pc.e[i] > 100) + { + hpcIndexVE->Fill(pc.index[i], pc.e[i]); // non gain matched energy + } + + // Gain Matching of PC wires + if (pc.index[i] >= 0 && pc.index[i] < 48) + { + // printf("index: %d, Old cathode energy: %d \n", pc.index[i],pc.e[i]); + auto it = slopeInterceptMap.find(pc.index[i]); + if (it != slopeInterceptMap.end()) + { + double slope = it->second.first; + double intercept = it->second.second; + // printf("slope: %f, intercept:%f\n" ,slope, intercept); + pc.e[i] = slope * pc.e[i] + intercept; + // printf("index: %d, New cathode energy: %d \n",pc.index[i], pc.e[i]); + } + hpcIndexVE_GM->Fill(pc.index[i], pc.e[i]); + // hPC_E[pc.index[i]]->Fill(pc.e[i]); // gain matched energy per channel + } + } + + std::vector> anodeHits = {}; + std::vector> cathodeHits = {}; + std::vector> corrcatMax = {}; + std::vector> corrcatnextMax = {}; + std::vector> commcat = {}; + int aID = 0; + int cID = 0; + float aE = 0; + float cE = 0; + float aESum = 0; + float cESum = 0; + float aEMax = 0; + float cEMax = 0; + float aEnextMax = 0; + float cEnextMax = 0; + int aIDMax = 0; + int cIDMax = 0; + int aIDnextMax = 0; + int cIDnextMax = 0; + + // Define the excluded SX3 and QQQ channels + // std::unordered_set excludeSX3 = {34, 35, 36, 37, 61, 62, 67, 73, 74, 75, 76, 77, 78, 79, 80, 93, 97, 100, 103, 108, 109, 110, 111, 112}; + // std::unordered_set excludeQQQ = {0, 17, 109, 110, 111, 112, 113, 119, 127, 128}; + // inCuth=false; + // inCutl=false; + // inPCCut=false; + for (int i = 0; i < pc.multi; i++) + { + if (pc.e[i] > 100 /*&& pc.multi < 7*/) + { + // creating a vector of pairs of anode and cathode hits + if (pc.index[i] < 24) + { + anodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + } + else if (pc.index[i] >= 24) + { + cathodeHits.push_back(std::pair(pc.index[i] - 24, pc.e[i])); + } + + for (int j = i + 1; j < pc.multi; j++) + { + // if(PCCoinc_cut1->IsInside(pc.index[i], pc.index[j]) || PCCoinc_cut2->IsInside(pc.index[i], pc.index[j])){ + // // hpcCoin->Fill(pc.index[i], pc.index[j]); + // inPCCut = true; + // } + hpcCoin->Fill(pc.index[i], pc.index[j]); + } + } + } + // sorting the anode and cathode hits in descending order of energy + std::sort(anodeHits.begin(), anodeHits.end(), [](const std::pair &a, const std::pair &b) + { return a.second > b.second; }); + std::sort(cathodeHits.begin(), cathodeHits.end(), [](const std::pair &a, const std::pair &b) + { return a.second > b.second; }); + + bool SiPCflag; + + corrcatMax.clear(); + if (anodeHits.size() >= 1 && cathodeHits.size() > 1) + { + if (((TMath::TanH(hitPos.Y() / hitPos.X())) > (TMath::TanH(a.Y() / a.X()) - TMath::PiOver4())) || ((TMath::TanH(hitPos.Y() / hitPos.X())) < (TMath::TanH(a.Y() / a.X()) + TMath::PiOver4()))) + { + + for (const auto &anode : anodeHits) + { + aID = anode.first; + aE = anode.second; + aESum += aE; + if (aE > aEMax) + { + aEMax = aE; + aIDMax = aID; + } + if (aE > aEnextMax && aE < aEMax) + { + aEnextMax = aE; + aIDnextMax = aID; + } + // for(const auto &cat : cathodeHits){ + // hAVCcoin->Fill(aID, cat.first); + // } + } + + // std::cout << " Anode iD : " << aIDMax << " Energy : " << aEMax << std::endl; + + // printf("aID : %d, aE : %f, cE : %f\n", aID, aE, cE); + for (const auto &cathode : cathodeHits) + { + cID = cathode.first; + cE = cathode.second; + // std::cout << "Cathode ID : " << cID << " Energy : " << cE << std::endl; + + hAVCcoin->Fill(aIDMax, cID); + + // This section of code is used to find the cathodes are correlated with the max and next max anodes, as well as to figure out if there are any common cathodes + // the anodes are correlated with the cathodes +/-3 from the anode number in the reverse order + + for (int j = -4; j < 3; j++) + { + if ((aIDMax + 24 + j) % 24 == 23 - cID) + /* the 23-cID is used to accomodate for the fact that the order of the cathodes was reversed relative top the physical geometry */ + // if (Crossover[aIDMax][cID][0].z != 9999999) + { + corrcatMax.push_back(std::pair(cID, cE)); + cESum += cE; + // printf("Max Anode : %d Correlated Cathode : %d Anode Energy : %f z value : %f \n", aIDMax, cID, cESum, Crossover[aIDMax][cID][1].z /*prints alpha*/); + // std::cout << " Cathode iD : " << cID << " Energy : " << cE << std::endl; + } + } + } + } + } + + TVector3 anodeIntersection; + anodeIntersection.Clear(); + // Implementing a method for PC reconstruction using a single Anode event + // if (anodeHits.size() == 1) + { + float x, y, z = 0; + for (const auto &corr : corrcatMax) + { + if (cESum > 0) + { + x += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].x; + y += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].y; + z += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].z; + // printf("Max Anode : %d Correlated Cathode : %d cathode Energy : %f cESum Energy : %f z value : %f \n", aIDMax, corr.first, corr.second, cESum, Crossover[aIDMax][corr.first][1].z /*prints alpha*/); + } + else + { + printf("Warning: No valid cathode hits to correlate with anode %d! \n", aIDMax); + } + // printf("EventID : %llu, Max Anode : %d Cathode: %d PC X and Y : (%f, %f) \n", entry, aIDMax, cID, Crossover[aIDMax][cID][0].x, Crossover[aIDMax][cID][0].y); + // for (int i = 0; i < sx3.multi; i++) + // { + // printf("EventID : %llu, HitPos X, Y, Z: %f %f %f SX3ID : %d %d \n", entry, hitPos.X(), hitPos.Y(), hitPos.Z(), sx3.id[i], sx3.ch[i]); + // } + + // for (int i = 0; i < qqq.multi; i++) + // { + // printf("Max Anode : %d Cathode: %d PC X and Y : %f %f \n", aIDMax, cID, Crossover[aIDMax][cID][0].x, Crossover[aIDMax][cID][0].y); + // printf("HitPos X, Y, Z, QQQID : %f %f %f %d \n", hitPos.X(), hitPos.Y(), hitPos.Z(), qqq.id[i]); + // } + } + anodeIntersection = TVector3(x, y, z); + // std::cout << "Anode Intersection " << anodeIntersection.Z() << " " << x << " " << y << " " << z << std::endl; + } + + if (anodeIntersection.Z() != 0) + { + hPCZProj->Fill(anodeIntersection.Z()); + } + // Filling the PC Z projection histogram + // std::cout << anodeIntersection.Z() << std::endl; + // hPCZProj->Fill(anodeIntersection.Z()); + + // } + + // inCuth = false; + // inCutl = false; + // inPCCut = false; + // for(int j=i+1;jIsInside(pc.index[i], pc.index[j]) || PCCoinc_cut2->IsInside(pc.index[i], pc.index[j])){ + // // hpcCoin->Fill(pc.index[i], pc.index[j]); + // inPCCut = true; + // } + // hpcCoin->Fill(pc.index[i], pc.index[j]); + // } + + // Check if the accumulated energies are within the defined ranges + // if (AnCatSum_high && AnCatSum_high->IsInside(aESum, cESum)) { + // inCuth = true; + // } + // if (AnCatSum_low && AnCatSum_low->IsInside(aESum, cESum)) { + // inCutl = true; + // } + + // Fill histograms based on the cut conditions + // if (inCuth && inPCCut) { + // hanVScatsum_hcut->Fill(aESum, cESum); + // } + // if (inCutl && inPCCut) { + // hanVScatsum_lcut->Fill(aESum, cESum); + // } + // for(auto anode : anodeHits){ + + // float aE = anode.second; + // aESum += aE; + // if(inPCCut){ + hanVScatsum->Fill(aEMax, cESum); + // } + + // if (sx3ecut) + // { + hCat4An->Fill(corrcatMax.size()); + hNosvAe->Fill(corrcatMax.size(), aEMax); + hAnodehits->Fill(anodeHits.size()); + // } + + // } + if (anodeHits.size() < 1) + { + hCat0An->Fill(cathodeHits.size()); + } + + if (HitNonZero && anodeIntersection.Z() != 0) + { + pw_contr.CalTrack2(hitPos, anodeIntersection); + hZProj->Fill(pw_contr.GetZ0()); + } + + // ########################################################### Track constrcution + + // ############################## DO THE KINEMATICS + + return kTRUE; + } + + void Analyzer::Terminate() + { + + // gStyle->SetOptStat("neiou"); + // TCanvas *canvas = new TCanvas("cANASEN", "ANASEN", 2000, 2000); + // canvas->Divide(3, 3); + + // // hsx3VpcIndex->Draw("colz"); + + // //=============================================== pad-1 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // hsx3IndexVE->Draw("colz"); + + // //=============================================== pad-2 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // hqqqIndexVE->Draw("colz"); + + // //=============================================== pad-3 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // hpcIndexVE->Draw("colz"); + + // //=============================================== pad-4 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // hsx3Coin->Draw("colz"); + + // //=============================================== pad-5 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // canvas->cd(padID)->SetLogz(true); + + // hqqqCoin->Draw("colz"); + + // //=============================================== pad-6 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // hpcCoin->Draw("colz"); + + // //=============================================== pad-7 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // // hsx3VpcIndex ->Draw("colz"); + // hsx3VpcE->Draw("colz"); + + // //=============================================== pad-8 + // padID++; + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + + // // hqqqVpcIndex ->Draw("colz"); + + // hqqqVpcE->Draw("colz"); + // //=============================================== pad-9 + // padID++; + + // // canvas->cd(padID)->DrawFrame(-50, -50, 50, 50); + // // hqqqPolar->Draw("same colz pol"); + + // canvas->cd(padID); + // canvas->cd(padID)->SetGrid(1); + // // hZProj->Draw(); + // hanVScatsum->Draw("colz"); + + TFile *outRoot = new TFile("Histograms.root", "RECREATE"); + + if (!outRoot->IsOpen()) + { + std::cerr << "Error opening file for writing!" << std::endl; + return; + } + + // // // Loop through histograms and write them to the ROOT file + for (int i = 0; i < 48; i++) + { + if (hPC_E[i] != nullptr) + { + hPC_E[i]->Write(); // Write histogram to file + } + } + outRoot->Close(); + } diff --git a/anasen_analysis_vignesh/Analyzer.h b/anasen_analysis_vignesh/Analyzer.h new file mode 100644 index 0000000..05d9073 --- /dev/null +++ b/anasen_analysis_vignesh/Analyzer.h @@ -0,0 +1,129 @@ +#ifndef Analyzer_h +#define Analyzer_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class Analyzer : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + Det misc; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + TBranch *b_miscMulti; //! + TBranch *b_miscID; //! + TBranch *b_miscCh; //! + TBranch *b_miscE; //! + TBranch *b_miscT; //! + TBranch *b_miscTf; //! + + + Analyzer(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~Analyzer() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(Analyzer,0); +}; + +#endif + +#ifdef Analyzer_cxx +void Analyzer::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + fChain->SetBranchAddress("miscMulti", &misc.multi, &b_miscMulti); + fChain->SetBranchAddress("miscID", &misc.id, &b_miscID); + fChain->SetBranchAddress("miscCh", &misc.ch, &b_miscCh); + fChain->SetBranchAddress("miscE", &misc.e, &b_miscE); + fChain->SetBranchAddress("miscT", &misc.t, &b_miscT); + // fChain->SetBranchAddress("miscF", &misc.tf, &b_miscTf); + + +} + +Bool_t Analyzer::Notify(){ + + return kTRUE; +} + +void Analyzer::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void Analyzer::SlaveTerminate(){ + +} + + +#endif // #ifdef Analyzer_cxx diff --git a/anasen_analysis_vignesh/Analyzer1.C b/anasen_analysis_vignesh/Analyzer1.C new file mode 100644 index 0000000..62c47d1 --- /dev/null +++ b/anasen_analysis_vignesh/Analyzer1.C @@ -0,0 +1,402 @@ +#define Analyzer1_cxx + +#include "Analyzer1.h" +#include +#include +#include +#include + +#include +#include + +#include "Armory/ClassSX3.h" +#include "Armory/ClassPW.h" + +#include "TVector3.h" + +TH2F * hsx3IndexVE; +TH2F * hqqqIndexVE; +TH2F * hpcIndexVE; + +TH2F * hsx3Coin; +TH2F * hqqqCoin; +TH2F * hpcCoin; + +TH2F * hqqqPolar; +TH2F * hsx3VpcIndex; +TH2F * hqqqVpcIndex; +TH2F * hqqqVpcE; +TH2F * hsx3VpcE; +TH2F * hanVScatsum; +int padID = 0; + +SX3 sx3_contr; +PW pw_contr; +TVector3 hitPos; +bool HitNonZero; + +TH1F * hZProj; + +void Analyzer1::Begin(TTree * /*tree*/){ + TString option = GetOption(); + + hsx3IndexVE = new TH2F("hsx3IndexVE", "SX3 index vs Energy; sx3 index ; Energy", 24*12, 0, 24*12, 400, 0, 5000); hsx3IndexVE->SetNdivisions( -612, "x"); + hqqqIndexVE = new TH2F("hqqqIndexVE", "QQQ index vs Energy; QQQ index ; Energy", 4*2*16, 0, 4*2*16, 400, 0, 5000); hqqqIndexVE->SetNdivisions( -1204, "x"); + hpcIndexVE = new TH2F("hpcIndexVE", "PC index vs Energy; PC index ; Energy", 2*24, 0, 2*24, 400, 0, 4000); hpcIndexVE->SetNdivisions( -1204, "x"); + + + hsx3Coin = new TH2F("hsx3Coin", "SX3 Coincident", 24*12, 0, 24*12, 24*12, 0, 24*12); + hqqqCoin = new TH2F("hqqqCoin", "QQQ Coincident", 4*2*16, 0, 4*2*16, 4*2*16, 0, 4*2*16); + hpcCoin = new TH2F("hpcCoin", "PC Coincident", 2*24, 0, 2*24, 2*24, 0, 2*24); + + hqqqPolar = new TH2F("hqqqPolar", "QQQ Polar ID", 16*4, -TMath::Pi(), TMath::Pi(),16, 10, 50); + + hsx3VpcIndex = new TH2F("hsx3Vpcindex", "sx3 vs pc; sx3 index; pc index", 24*12, 0, 24*12, 48, 0, 48); + hsx3VpcIndex->SetNdivisions( -612, "x"); + hsx3VpcIndex->SetNdivisions( -12, "y"); + hqqqVpcIndex = new TH2F("hqqqVpcindex", "qqq vs pc; qqq index; pc index", 4*2*16, 0, 4*2*16, 48, 0, 48); + hqqqVpcIndex->SetNdivisions( -612, "x"); + hqqqVpcIndex->SetNdivisions( -12, "y"); + + hqqqVpcE = new TH2F("hqqqVpcEnergy", "qqq vs pc; qqq energy; pc energy", 400, 0, 5000, 400, 0, 5000); + hqqqVpcE->SetNdivisions( -612, "x"); + hqqqVpcE->SetNdivisions( -12, "y"); + + hsx3VpcE = new TH2F("hsx3VpcEnergy", "sx3 vs pc; sx3 energy; pc energy", 400, 0, 5000, 400, 0, 5000); + hsx3VpcE->SetNdivisions( -612, "x"); + hsx3VpcE->SetNdivisions( -12, "y"); + + hZProj = new TH1F("hZProj", "Z Projection", 1200, -600, 600); + + hanVScatsum = new TH2F("hanVScatsum", "Anode vs Cathode Sum; Anode E; Cathode E", 400,0 , 10000, 400, 0 , 16000); + + sx3_contr.ConstructGeo(); + pw_contr.ConstructGeo(); + +} + + + + +Bool_t Analyzer1::Process(Long64_t entry){ + + // if ( entry > 100 ) return kTRUE; + + hitPos.Clear(); + HitNonZero = false; + + // if( entry > 1) return kTRUE; + // printf("################### ev : %llu \n", entry); + + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + // sx3.Print(); + + //########################################################### Raw data + // //======================= SX3 + + std::vector> ID; // first = id, 2nd = index + for( int i = 0; i < sx3.multi; i ++){ + ID.push_back(std::pair(sx3.id[i], i)); + + hsx3IndexVE->Fill( sx3.index[i], sx3.e[i] ); + + for( int j = i+1; j < sx3.multi; j++){ + hsx3Coin->Fill( sx3.index[i], sx3.index[j]); + } + + for( int j = 0; j < pc.multi; j++){ + hsx3VpcIndex->Fill( sx3.index[i], pc.index[j] ); + // if( sx3.ch[index] > 8 ){ + // hsx3VpcE->Fill( sx3.e[i], pc.e[j] ); + // } + } + } + + + if( ID.size() > 0 ){ + std::sort(ID.begin(), ID.end(), [](const std::pair & a, const std::pair & b) { + return a.first < b.first; + } ); + // printf("##############################\n"); + // for( size_t i = 0; i < ID.size(); i++) printf("%zu | %d %d \n", i, ID[i].first, ID[i].second ); + + std::vector> sx3ID; + sx3ID.push_back(ID[0]); + bool found = false; + for( size_t i = 1; i < ID.size(); i++){ + if( ID[i].first == sx3ID.back().first) { + sx3ID.push_back(ID[i]); + if( sx3ID.size() >= 3) { + found = true; + } + }else{ + if( !found ){ + sx3ID.clear(); + sx3ID.push_back(ID[i]); + } + } + } + + // printf("---------- sx3ID Multi : %zu \n", sx3ID.size()); + + if( found ){ + int sx3ChUp, sx3ChDn, sx3ChBk; + float sx3EUp, sx3EDn; + // printf("------ sx3 ID : %d, multi: %zu\n", sx3ID[0].first, sx3ID.size()); + for( size_t i = 0; i < sx3ID.size(); i++ ){ + int index = sx3ID[i].second; + // printf(" %zu | index %d | ch : %d, energy : %d \n", i, index, sx3.ch[index], sx3.e[index]); + + + if( sx3.ch[index] < 8 ){ + if( sx3.ch[index] % 2 == 0) { + sx3ChDn = sx3.ch[index]; + sx3EDn = sx3.e[index]; + }else{ + sx3ChUp = sx3.ch[index]; + sx3EUp = sx3.e[index]; + } + }else{ + sx3ChBk = sx3.ch[index]; + } + for( int j = 0; j < pc.multi; j++){ + // hsx3VpcIndex->Fill( sx3.index[i], pc.index[j] ); + if( sx3.ch[index] > 8 ){ + hsx3VpcE->Fill( sx3.e[i], pc.e[j] ); + // hpcIndexVE->Fill( pc.index[i], pc.e[i] ); + } + } + } + + sx3_contr.CalSX3Pos(sx3ID[0].first, sx3ChUp, sx3ChDn, sx3ChBk, sx3EUp, sx3EDn); + hitPos = sx3_contr.GetHitPos(); + HitNonZero = true; + // hitPos.Print(); + } + + } + + + // //======================= QQQ + for( int i = 0; i < qqq.multi; i ++){ + // for( int j = 0; j < pc.multi; j++){ + // if(pc.index[j]==4){ + hqqqIndexVE->Fill( qqq.index[i], qqq.e[i] ); + // } + // } + for( int j = 0; j < qqq.multi; j++){ + if ( j == i ) continue; + hqqqCoin->Fill( qqq.index[i], qqq.index[j]); + } + + + for( int j = i + 1; j < qqq.multi; j++){ + for( int k = 0; k < pc.multi; k++){ + if(pc.index[k]<24 && pc.e[k]>50 ){ + hqqqVpcE->Fill( qqq.e[i], pc.e[k] ); + // hpcIndexVE->Fill( pc.index[i], pc.e[i] ); + hqqqVpcIndex->Fill( qqq.index[i], pc.index[j] ); + + } + // } + } + // if( qqq.used[i] == true ) continue; + + //if( qqq.id[i] == qqq.id[j] && (16 - qqq.ch[i]) * (16 - qqq.ch[j]) < 0 ){ // must be same detector and wedge and ring + if( qqq.id[i] == qqq.id[j] ){ // must be same detector + + int chWedge = -1; + int chRing = -1; + if( qqq.ch[i] < qqq.ch[j]){ + chRing = qqq.ch[j] - 16; + chWedge = qqq.ch[i]; + }else{ + chRing = qqq.ch[i]; + chWedge = qqq.ch[j] - 16; + } + + // printf(" ID : %d , chWedge : %d, chRing : %d \n", qqq.id[i], chWedge, chRing); + + double theta = -TMath::Pi()/2 + 2*TMath::Pi()/16/4.*(qqq.id[i]*16 + chWedge +0.5); + double rho = 10.+40./16.*(chRing+0.5); + // if(qqq.e[i]>50){ + hqqqPolar->Fill( theta, rho); + // } + // qqq.used[i] = true; + // qqq.used[j] = true; + + if( !HitNonZero ){ + double x = rho * TMath::Cos(theta); + double y = rho * TMath::Sin(theta); + hitPos.SetXYZ(x, y, 23 + 75 + 30); + HitNonZero = true; + } + } + } + + + } + // //======================= PC + + ID.clear(); + int counter=0; + std::vector> E; + E.clear(); + for( int i = 0; i < pc.multi; i ++){ + + if( pc.e[i] > 100 ) ID.push_back(std::pair(pc.id[i], i)); + if( pc.e[i] > 100 ) E.push_back(std::pair(pc.index[i], pc.e[i])); + + hpcIndexVE->Fill( pc.index[i], pc.e[i] ); + + for( int j = i+1; j < pc.multi; j++){ + hpcCoin->Fill( pc.index[i], pc.index[j]); + + } + + } + // for( size_t i = 0; i < E.size(); i++) printf("%zu | %d %d \n", i, E[i].first, E[i].second ); + + if( E.size()>=3 ){ + + int aID = 0; + int cID = 0; + + float aE = 0; + float cE = 0; + bool multi_an =false; + // if( ID[0].first < 1 ) { + // aID = pc.ch[ID[0].second]; + // cID = pc.ch[ID[1].second]; + // }else{ + // cID = pc.ch[ID[0].second]; + // aID = pc.ch[ID[1].second]; + // } + // printf("anode= %d, cathode = %d\n", aID, cID); + + // for( int k = 0; k < qqq.multi; k++){ + // if(qqq.index[k]==75 && pc.index[k]==2 && pc.e[k]>100){ + for(int l=0;l=24){ + cE = E[l].second + cE; + } + } + // } + // } + hanVScatsum->Fill(aE,cE); + + if( ID[0].first < 1 ) { + aID = pc.ch[ID[0].second]; + cID = pc.ch[ID[1].second]; + }else{ + cID = pc.ch[ID[0].second]; + aID = pc.ch[ID[1].second]; + } + + if( HitNonZero){ + pw_contr.CalTrack( hitPos, aID, cID); + hZProj->Fill(pw_contr.GetZ0()); + } + + + } + + + + //########################################################### Track constrcution + + + //############################## DO THE KINEMATICS + + + return kTRUE; +} + +void Analyzer1::Terminate(){ + + gStyle->SetOptStat("neiou"); + TCanvas * canvas = new TCanvas("cANASEN", "ANASEN", 2000, 2000); + canvas->Divide(3,3); + + //hsx3VpcIndex->Draw("colz"); + + //=============================================== pad-1 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hsx3IndexVE->Draw("colz"); + + //=============================================== pad-2 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hqqqIndexVE->Draw("colz"); + + //=============================================== pad-3 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hpcIndexVE->Draw("colz"); + + //=============================================== pad-4 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hsx3Coin->Draw("colz"); + + //=============================================== pad-5 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + canvas->cd(padID)->SetLogz(true); + + hqqqCoin->Draw("colz"); + + //=============================================== pad-6 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hpcCoin->Draw("colz"); + + //=============================================== pad-7 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + // hsx3VpcIndex ->Draw("colz"); + hsx3VpcE->Draw("colz") ; + + //=============================================== pad-8 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + // hqqqVpcIndex ->Draw("colz"); + + hqqqVpcE ->Draw("colz"); + //=============================================== pad-9 + padID ++; + + // canvas->cd(padID)->DrawFrame(-50, -50, 50, 50); + // hqqqPolar->Draw("same colz pol"); + + canvas->cd(padID); canvas->cd(padID)->SetGrid(1); +// hZProj->Draw(); + hanVScatsum->Draw("colz"); + +} diff --git a/anasen_analysis_vignesh/Analyzer1.h b/anasen_analysis_vignesh/Analyzer1.h new file mode 100644 index 0000000..9d9d3a7 --- /dev/null +++ b/anasen_analysis_vignesh/Analyzer1.h @@ -0,0 +1,114 @@ +#ifndef Analyzer1_h +#define Analyzer1_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class Analyzer1 : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + + Analyzer1(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~Analyzer1() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(Analyzer1,0); +}; + +#endif + +#ifdef Analyzer1_cxx +void Analyzer1::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + +} + +Bool_t Analyzer1::Notify(){ + + return kTRUE; +} + +void Analyzer1::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void Analyzer1::SlaveTerminate(){ + +} + + +#endif // #ifdef Analyzer_cxx diff --git a/anasen_analysis_vignesh/Armory/ANASEN_model.C b/anasen_analysis_vignesh/Armory/ANASEN_model.C new file mode 100644 index 0000000..e21d4c6 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ANASEN_model.C @@ -0,0 +1,121 @@ +#include "TGeoManager.h" +#include "TGeoVolume.h" +#include "TGeoBBox.h" +#include "TCanvas.h" +#include "TPolyMarker3D.h" +#include "TPolyLine3D.h" + +#include "TMath.h" + +void ANASEN_model(int anodeID1 = -1, int anodeID2 = -1, int cathodeID1 = -1, int cathodeID2 = -1 ) { + + // Create ROOT manager and master volume + TGeoManager *geom = new TGeoManager("Detector", "ANASEN"); + + //--- define some materials + TGeoMaterial *matVacuum = new TGeoMaterial("Vacuum", 0,0,0); + TGeoMaterial *matAl = new TGeoMaterial("Al", 26.98,13,2.7); + //--- define some media + TGeoMedium *Vacuum = new TGeoMedium("Vacuum",1, matVacuum); + TGeoMedium *Al = new TGeoMedium("Root Material",2, matAl); + + //--- make the top container volume + Double_t worldx = 200.; //mm + Double_t worldy = 200.; //mm + Double_t worldz = 200.; //mm + TGeoVolume *worldBox = geom->MakeBox("ROOT", Vacuum, worldx, worldy, worldz); + geom->SetTopVolume(worldBox); + + //--- making axis + TGeoVolume *axisX = geom->MakeTube("axisX", Al, 0, 0.1, 5.); + axisX->SetLineColor(1); + worldBox->AddNode(axisX, 1, new TGeoCombiTrans(5, 0, 0., new TGeoRotation("rotA", 90., 90., 0.))); + + TGeoVolume *axisY = geom->MakeTube("axisY", Al, 0, 0.1, 5.); + axisY->SetLineColor(1); + worldBox->AddNode(axisY, 1, new TGeoCombiTrans(0, 5, 0., new TGeoRotation("rotB", 0., 90., 0.))); + + TGeoVolume *axisZ = geom->MakeTube("axisZ", Al, 0, 0.1, 5.); + axisZ->SetLineColor(1); + worldBox->AddNode(axisZ, 1, new TGeoTranslation(0, 0, 5)); + + //--- making ANASEN + const int nWire = 24; + const int wireShift = 3; + const int zLen = 300; //mm + const int radiusA = 38; + const int radiusC = 43; + + //.......... convert to wire center dimensions + double dAngle = wireShift * TMath::TwoPi() / nWire; + double radiusAnew = radiusA * TMath::Cos( dAngle / 2.); + double wireALength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusA * TMath::Sin(dAngle/2),2) ); + double wireATheta = TMath::ATan2( 2* radiusA * TMath::Sin( dAngle / 2.), zLen); + + // printf(" dAngle : %f\n", dAngle); + // printf(" newRadius : %f\n", radiusAnew); + // printf("wireLength : %f\n", wireALength); + // printf("wire Theta : %f\n", wireATheta); + + TGeoVolume *pcA = geom->MakeTube("tub1", Al, 0, 0.01, wireALength/2); + pcA->SetLineColor(4); + + for( int i = 0; i < nWire; i++){ + if( anodeID2 >= 0 && (i < anodeID1 || i > anodeID2) ) continue; + worldBox->AddNode(pcA, i+1, new TGeoCombiTrans( radiusAnew * TMath::Cos( TMath::TwoPi() / nWire *i + dAngle / 2), + radiusAnew * TMath::Sin( TMath::TwoPi() / nWire *i + dAngle / 2), + 0, + new TGeoRotation("rot1", 360/ nWire * (i + wireShift/2.), wireATheta * 180/ TMath::Pi(), 0.))); + + } + + double radiusCnew = radiusC * TMath::Cos( dAngle / 2.); + double wireCLength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusC * TMath::Sin(dAngle/2),2) ); + double wireCTheta = TMath::ATan2( 2* radiusC * TMath::Sin( dAngle / 2.), zLen); + + TGeoVolume *pcC = geom->MakeTube("tub2", Al, 0, 0.01, wireCLength/2); + pcC->SetLineColor(6); + for( int i = 0; i < nWire; i++){ + if( cathodeID2 >= 0 && (i < cathodeID1 || i > cathodeID2) ) continue; + worldBox->AddNode(pcC, i+1, new TGeoCombiTrans( radiusCnew * TMath::Cos( TMath::TwoPi() / nWire *i - dAngle/2), + radiusCnew * TMath::Sin( TMath::TwoPi() / nWire *i - dAngle/2), + 0, + new TGeoRotation("rot1", 360/ nWire * (i - wireShift/2.), -wireCTheta * 180/ TMath::Pi(), 0.))); + } + + const int nSX3 = 12; + const int sx3Radius = 88; + const int sx3Width = 40; + const int sx3Length = 75; + const int sx3Gap = 5; + + TGeoVolume * sx3 = geom->MakeBox("box", Al, 0.1, sx3Width/2, sx3Length/2); + sx3->SetLineColor(kGreen+3); + for( int i = 0; i < nSX3; i++){ + worldBox->AddNode(sx3, 2*i+1., new TGeoCombiTrans( sx3Radius * TMath::Cos( TMath::TwoPi() / nSX3 * (i + 0.5)), + sx3Radius * TMath::Sin( TMath::TwoPi() / nSX3 * (i + 0.5)), + sx3Length/2+sx3Gap, + new TGeoRotation("rot1", 360/nSX3 * (i + 0.5), 0., 0.))); + + worldBox->AddNode(sx3, 2*i+2., new TGeoCombiTrans( sx3Radius * TMath::Cos( TMath::TwoPi() / nSX3 * (i + 0.5)), + sx3Radius * TMath::Sin( TMath::TwoPi() / nSX3 * (i + 0.5)), + -sx3Length/2-sx3Gap, + new TGeoRotation("rot1", 360/nSX3 * (i + 0.5), 0., 0.))); + } + + const int qqqR1 = 50; + const int qqqR2 = 100; + TGeoVolume *qqq = geom->MakeTubs("qqq", Al, qqqR1, qqqR2, 0.5, 5, 85); + qqq->SetLineColor(7); + for( int i = 0; i < 4; i++){ + worldBox->AddNode(qqq, i+1, new TGeoCombiTrans( 0, + 0, + 100, + new TGeoRotation("rot1", 360/4 * (i), 0., 0.))); + } + + geom->CloseGeometry(); + + geom->SetVisLevel(4); + worldBox->Draw("ogle"); +} diff --git a/anasen_analysis_vignesh/Armory/Armory/ANASEN_model.C b/anasen_analysis_vignesh/Armory/Armory/ANASEN_model.C new file mode 100644 index 0000000..e21d4c6 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/ANASEN_model.C @@ -0,0 +1,121 @@ +#include "TGeoManager.h" +#include "TGeoVolume.h" +#include "TGeoBBox.h" +#include "TCanvas.h" +#include "TPolyMarker3D.h" +#include "TPolyLine3D.h" + +#include "TMath.h" + +void ANASEN_model(int anodeID1 = -1, int anodeID2 = -1, int cathodeID1 = -1, int cathodeID2 = -1 ) { + + // Create ROOT manager and master volume + TGeoManager *geom = new TGeoManager("Detector", "ANASEN"); + + //--- define some materials + TGeoMaterial *matVacuum = new TGeoMaterial("Vacuum", 0,0,0); + TGeoMaterial *matAl = new TGeoMaterial("Al", 26.98,13,2.7); + //--- define some media + TGeoMedium *Vacuum = new TGeoMedium("Vacuum",1, matVacuum); + TGeoMedium *Al = new TGeoMedium("Root Material",2, matAl); + + //--- make the top container volume + Double_t worldx = 200.; //mm + Double_t worldy = 200.; //mm + Double_t worldz = 200.; //mm + TGeoVolume *worldBox = geom->MakeBox("ROOT", Vacuum, worldx, worldy, worldz); + geom->SetTopVolume(worldBox); + + //--- making axis + TGeoVolume *axisX = geom->MakeTube("axisX", Al, 0, 0.1, 5.); + axisX->SetLineColor(1); + worldBox->AddNode(axisX, 1, new TGeoCombiTrans(5, 0, 0., new TGeoRotation("rotA", 90., 90., 0.))); + + TGeoVolume *axisY = geom->MakeTube("axisY", Al, 0, 0.1, 5.); + axisY->SetLineColor(1); + worldBox->AddNode(axisY, 1, new TGeoCombiTrans(0, 5, 0., new TGeoRotation("rotB", 0., 90., 0.))); + + TGeoVolume *axisZ = geom->MakeTube("axisZ", Al, 0, 0.1, 5.); + axisZ->SetLineColor(1); + worldBox->AddNode(axisZ, 1, new TGeoTranslation(0, 0, 5)); + + //--- making ANASEN + const int nWire = 24; + const int wireShift = 3; + const int zLen = 300; //mm + const int radiusA = 38; + const int radiusC = 43; + + //.......... convert to wire center dimensions + double dAngle = wireShift * TMath::TwoPi() / nWire; + double radiusAnew = radiusA * TMath::Cos( dAngle / 2.); + double wireALength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusA * TMath::Sin(dAngle/2),2) ); + double wireATheta = TMath::ATan2( 2* radiusA * TMath::Sin( dAngle / 2.), zLen); + + // printf(" dAngle : %f\n", dAngle); + // printf(" newRadius : %f\n", radiusAnew); + // printf("wireLength : %f\n", wireALength); + // printf("wire Theta : %f\n", wireATheta); + + TGeoVolume *pcA = geom->MakeTube("tub1", Al, 0, 0.01, wireALength/2); + pcA->SetLineColor(4); + + for( int i = 0; i < nWire; i++){ + if( anodeID2 >= 0 && (i < anodeID1 || i > anodeID2) ) continue; + worldBox->AddNode(pcA, i+1, new TGeoCombiTrans( radiusAnew * TMath::Cos( TMath::TwoPi() / nWire *i + dAngle / 2), + radiusAnew * TMath::Sin( TMath::TwoPi() / nWire *i + dAngle / 2), + 0, + new TGeoRotation("rot1", 360/ nWire * (i + wireShift/2.), wireATheta * 180/ TMath::Pi(), 0.))); + + } + + double radiusCnew = radiusC * TMath::Cos( dAngle / 2.); + double wireCLength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusC * TMath::Sin(dAngle/2),2) ); + double wireCTheta = TMath::ATan2( 2* radiusC * TMath::Sin( dAngle / 2.), zLen); + + TGeoVolume *pcC = geom->MakeTube("tub2", Al, 0, 0.01, wireCLength/2); + pcC->SetLineColor(6); + for( int i = 0; i < nWire; i++){ + if( cathodeID2 >= 0 && (i < cathodeID1 || i > cathodeID2) ) continue; + worldBox->AddNode(pcC, i+1, new TGeoCombiTrans( radiusCnew * TMath::Cos( TMath::TwoPi() / nWire *i - dAngle/2), + radiusCnew * TMath::Sin( TMath::TwoPi() / nWire *i - dAngle/2), + 0, + new TGeoRotation("rot1", 360/ nWire * (i - wireShift/2.), -wireCTheta * 180/ TMath::Pi(), 0.))); + } + + const int nSX3 = 12; + const int sx3Radius = 88; + const int sx3Width = 40; + const int sx3Length = 75; + const int sx3Gap = 5; + + TGeoVolume * sx3 = geom->MakeBox("box", Al, 0.1, sx3Width/2, sx3Length/2); + sx3->SetLineColor(kGreen+3); + for( int i = 0; i < nSX3; i++){ + worldBox->AddNode(sx3, 2*i+1., new TGeoCombiTrans( sx3Radius * TMath::Cos( TMath::TwoPi() / nSX3 * (i + 0.5)), + sx3Radius * TMath::Sin( TMath::TwoPi() / nSX3 * (i + 0.5)), + sx3Length/2+sx3Gap, + new TGeoRotation("rot1", 360/nSX3 * (i + 0.5), 0., 0.))); + + worldBox->AddNode(sx3, 2*i+2., new TGeoCombiTrans( sx3Radius * TMath::Cos( TMath::TwoPi() / nSX3 * (i + 0.5)), + sx3Radius * TMath::Sin( TMath::TwoPi() / nSX3 * (i + 0.5)), + -sx3Length/2-sx3Gap, + new TGeoRotation("rot1", 360/nSX3 * (i + 0.5), 0., 0.))); + } + + const int qqqR1 = 50; + const int qqqR2 = 100; + TGeoVolume *qqq = geom->MakeTubs("qqq", Al, qqqR1, qqqR2, 0.5, 5, 85); + qqq->SetLineColor(7); + for( int i = 0; i < 4; i++){ + worldBox->AddNode(qqq, i+1, new TGeoCombiTrans( 0, + 0, + 100, + new TGeoRotation("rot1", 360/4 * (i), 0., 0.))); + } + + geom->CloseGeometry(); + + geom->SetVisLevel(4); + worldBox->Draw("ogle"); +} diff --git a/anasen_analysis_vignesh/Armory/Armory/ClassAnasen.h b/anasen_analysis_vignesh/Armory/Armory/ClassAnasen.h new file mode 100644 index 0000000..90585b7 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/ClassAnasen.h @@ -0,0 +1,314 @@ +#ifndef ClassAnasen_h +#define ClassAnasen_h + +#include +#include +#include + +#include "TGeoManager.h" +#include "TGeoVolume.h" +#include "TGeoBBox.h" +#include "TCanvas.h" +#include "TPolyMarker3D.h" +#include "TPolyLine3D.h" +#include "TRandom.h" + +#include "ClassSX3.h" +#include "ClassPW.h" + +class ANASEN{ +public: + ANASEN(); + ~ANASEN(); + + void SetUncertainties(double sx3W, double sx3L, double anode, double cathode){ + sigmaA = anode; + sigmaC = cathode; + sigmaW = sx3W; + sigmaL = sx3L; + } + + void DrawTrack(TVector3 pos, TVector3 direction, bool drawEstimatedTrack = false); + void DrawDeducedTrack(TVector3 sx3Pos, int anodeID, int cathodeID); + void DrawAnasen(int anodeID1 = -1, + int anodeID2 = -1, + int cathodeID1 = -1, + int cathodeID2 = -1, + int sx3ID = -1, + bool DrawQQQ = false ); + + + + PW * GetPW() {return pw;} + SX3 * GetSX3() {return sx3;} + +private: + + PW * pw; + SX3 * sx3; + + double sigmaA, sigmaC; // pw + double sigmaW, sigmaL; // sx3 + + const float qqqR1 = 50; + const float qqqR2 = 100; + const float qqqZPos = 23 + 75 + 30; + + void CalGeometry(); + + TGeoManager *geom; + TGeoVolume *worldBox; + + void Construct3DModel(int anodeID1 = -1, + int anodeID2 = -1, + int cathodeID1 = -1, + int cathodeID2 = -1, + int sx3ID = -1, + bool DrawQQQ = true); + +}; + +//!============================================== +inline ANASEN::ANASEN(){ + + pw = new PW(); + sx3 = new SX3(); + + CalGeometry(); + + geom = nullptr; + worldBox = nullptr; + +} + +inline ANASEN::~ANASEN(){ + + delete geom; + + delete pw; + delete sx3; + +} + +//!============================================== +inline void ANASEN::CalGeometry(){ + + sx3->ConstructGeo(); + pw->ConstructGeo(); + +} + +inline void ANASEN::Construct3DModel(int anodeID1, int anodeID2, int cathodeID1, int cathodeID2, int sx3ID, bool DrawQQQ ){ + + if( geom ) delete geom; + + // Create ROOT manager and master volume + geom = new TGeoManager("Detector", "ANASEN"); + + //--- define some materials + TGeoMaterial *matVacuum = new TGeoMaterial("Vacuum", 0,0,0); + TGeoMaterial *matAl = new TGeoMaterial("Al", 26.98,13,2.7); + //--- define some media + TGeoMedium *Vacuum = new TGeoMedium("Vacuum",1, matVacuum); + TGeoMedium *Al = new TGeoMedium("Root Material",2, matAl); + + //--- make the top container volume + Double_t worldx = 200.; //mm + Double_t worldy = 200.; //mm + Double_t worldz = 200.; //mm + worldBox = geom->MakeBox("ROOT", Vacuum, worldx, worldy, worldz); + geom->SetTopVolume(worldBox); + + //--- making axis + TGeoVolume *axisX = geom->MakeTube("axisX", Al, 0, 0.1, 5.); + axisX->SetLineColor(1); + worldBox->AddNode(axisX, 1, new TGeoCombiTrans(5, 0, 0., new TGeoRotation("rotA", 90., 90., 0.))); + TGeoVolume *axisY = geom->MakeTube("axisY", Al, 0, 0.1, 5.); + axisY->SetLineColor(1); + worldBox->AddNode(axisY, 1, new TGeoCombiTrans(0, 5, 0., new TGeoRotation("rotB", 0., 90., 0.))); + TGeoVolume *axisZ = geom->MakeTube("axisZ", Al, 0, 0.1, 5.); + axisZ->SetLineColor(1); + worldBox->AddNode(axisZ, 1, new TGeoTranslation(0, 0, 5)); + + //.......... convert to wire center dimensions + TGeoVolume *pcA = geom->MakeTube("tub1", Al, 0, 0.01, pw->GetAnodeLength()/2); + pcA->SetLineColor(4); + + int startID = 0; + int endID = pw->GetNumWire() - 1; + + if( anodeID1 >= 0 && anodeID2 >= 0 ){ + startID = anodeID1; + endID = anodeID2; + if( anodeID1 > anodeID2 ) { + endID = pw->GetNumWire() + anodeID2; + } + } + + for( int i = startID; i <= endID; i++){ + TVector3 a = pw->GetAnodneMid(i); + double wireTheta = pw->GetAnodeTheta(i) * TMath::RadToDeg(); + double wirePhi = pw->GetAnodePhi(i) * TMath::RadToDeg() + 90; + + worldBox->AddNode(pcA, i+1, new TGeoCombiTrans( a.X(), + a.Y(), + a.Z(), + new TGeoRotation("rot1", wirePhi, wireTheta, 0.))); + } + + TGeoVolume *pcC = geom->MakeTube("tub2", Al, 0, 0.01, pw->GetCathodeLength()/2); + pcC->SetLineColor(6); + + startID = 0; + endID = pw->GetNumWire() - 1; + + if( cathodeID1 >= 0 && cathodeID2 >= 0 ){ + startID = cathodeID1; + endID = cathodeID2; + if( cathodeID1 > cathodeID2 ) { + endID = pw->GetNumWire() + cathodeID2; + } + } + + for( int i = startID; i <= endID; i++){ + TVector3 a = pw->GetCathodneMid(i); + double wireTheta = pw->GetCathodeTheta(i) * TMath::RadToDeg(); + double wirePhi = pw->GetCathodePhi(i) * TMath::RadToDeg() + 90; + + worldBox->AddNode(pcC, i+1, new TGeoCombiTrans( a.X(), + a.Y(), + a.Z(), + new TGeoRotation("rot1", wirePhi , wireTheta, 0.))); + } + + TGeoVolume * sx3Det = geom->MakeBox("box", Al, 0.1, sx3->GetWidth()/2, sx3->GetLength()/2); + sx3Det->SetLineColor(kGreen+3); + + for( int i = 0; i < sx3->GetNumDet(); i++){ + if( sx3ID != -1 && i != sx3ID ) continue; + TVector3 aUp = sx3->GetUpMid(i); // center of the SX3 upstream + TVector3 aDn = sx3->GetDnMid(i); // center of the SX3 Downstream + double phi = sx3->GetDetPhi(i) * TMath::RadToDeg() + 90; + + worldBox->AddNode(sx3Det, 2*i+1., new TGeoCombiTrans( aUp.X(), + aUp.Y(), + aUp.Z(), + new TGeoRotation("rot1", phi, 0., 0.))); + worldBox->AddNode(sx3Det, 2*i+1., new TGeoCombiTrans( aDn.X(), + aDn.Y(), + aDn.Z(), + new TGeoRotation("rot1", phi, 0., 0.))); + } + + if( DrawQQQ ){ + TGeoVolume *qqq = geom->MakeTubs("qqq", Al, qqqR1, qqqR2, 0.5, 5, 85); + qqq->SetLineColor(7); + for( int i = 0; i < 4; i++){ + worldBox->AddNode(qqq, i+1, new TGeoCombiTrans( 0, + 0, + qqqZPos, + new TGeoRotation("rot1", 360/4 * (i), 0., 0.))); + } + } + +} + +//!============================================== Drawing functions +inline void ANASEN::DrawAnasen(int anodeID1, int anodeID2, int cathodeID1, int cathodeID2, int sx3ID, bool DrawQQQ ){ + + Construct3DModel(anodeID1, anodeID2, cathodeID1, cathodeID2, sx3ID, DrawQQQ); + + geom->CloseGeometry(); + geom->SetVisLevel(4); + worldBox->Draw("ogle"); + +} + +inline void ANASEN::DrawTrack(TVector3 pos, TVector3 direction, bool drawEstimatedTrack){ + + pw->FindWireID(pos, direction); + sx3->FindSX3Pos(pos, direction); + + std::pair wireID = pw->GetNearestID(); + + Construct3DModel(wireID.first, wireID.first, wireID.second, wireID.second, -1, false); + + double theta = direction.Theta() * TMath::RadToDeg(); + double phi = direction.Phi() * TMath::RadToDeg(); + // printf("Theta, Phi = %.2f %.2f \n", theta, phi); + // pos.Print(); + TGeoVolume * Track = geom->MakeTube("track", 0, 0, 0.1, 150.); + Track->SetLineColor(kRed); + worldBox->AddNode(Track, 1, new TGeoCombiTrans( pos.X(), pos.Y(), pos.Z(), new TGeoRotation("rotA", phi + 90, theta, 0.))); + + TGeoVolume * startPos = geom->MakeSphere("startPos", 0, 0, 3); + startPos->SetLineColor(kBlack); + worldBox->AddNode(startPos, 3, new TGeoCombiTrans( pos.X(), pos.Y(), pos.Z(), new TGeoRotation("rotA", 0, 0, 0.))); + + if( sx3->GetID() >= 0 ){ + //TVector3 hitPos = sx3->GetHitPos(); + TVector3 hitPos = sx3->GetHitPosWithSigma(sigmaW, sigmaL); + + TGeoVolume * hit = geom->MakeSphere("hitpos", 0, 0, 3); + hit->SetLineColor(kRed); + worldBox->AddNode(hit, 2, new TGeoCombiTrans( hitPos.X(), hitPos.Y(), hitPos.Z(), new TGeoRotation("rotA", 0, 0, 0.))); + + if( drawEstimatedTrack ){ + + {//===== simple + pw->CalTrack(hitPos, wireID.first, wireID.second, true); + + double thetaDeduce = pw->GetTrackTheta() * TMath::RadToDeg(); + double phiDeduce = pw->GetTrackPhi() * TMath::RadToDeg(); + + TGeoVolume * trackDeduce = geom->MakeTube("trackDeduce", 0, 0, 0.1, 100.); + trackDeduce->SetLineColor(kOrange); + worldBox->AddNode(trackDeduce, 1, new TGeoCombiTrans( hitPos.X(), hitPos.Y(), hitPos.Z(), new TGeoRotation("rotA", phiDeduce + 90, thetaDeduce, 0.))); + } + + {//===== complicated + PWHitInfo hitInfo = pw->GetHitInfo(); + pw->CalTrack2(hitPos, hitInfo, sigmaA, sigmaC, true); + + double thetaDeduce = pw->GetTrackTheta() * TMath::RadToDeg(); + double phiDeduce = pw->GetTrackPhi() * TMath::RadToDeg(); + + TGeoVolume * trackDeduce2 = geom->MakeTube("trackDeduce2", 0, 0, 0.1, 100.); + trackDeduce2->SetLineColor(kGreen); + worldBox->AddNode(trackDeduce2, 1, new TGeoCombiTrans( hitPos.X(), hitPos.Y(), hitPos.Z(), new TGeoRotation("rotA", phiDeduce + 90, thetaDeduce, 0.))); + } + } + + } + + geom->CloseGeometry(); + geom->SetVisLevel(4); + worldBox->Draw("ogle"); + +} + +inline void ANASEN::DrawDeducedTrack(TVector3 sx3Pos, int anodeID, int cathodeID){ + + pw->CalTrack(sx3Pos, anodeID, cathodeID); + + Construct3DModel(anodeID, anodeID, cathodeID, cathodeID, -1, false); + + double theta = pw->GetTrackTheta() * TMath::RadToDeg(); + double phi = pw->GetTrackPhi() * TMath::RadToDeg(); + + TGeoVolume * Track = geom->MakeTube("axisX", 0, 0, 0.1, 100.); + Track->SetLineColor(kRed); + worldBox->AddNode(Track, 1, new TGeoCombiTrans( sx3Pos.X(), sx3Pos.Y(), sx3Pos.Z(), new TGeoRotation("rotA", phi + 90, theta, 0.))); + + TGeoVolume * hit = geom->MakeSphere("hitpos", 0, 0, 3); + hit->SetLineColor(kRed); + worldBox->AddNode(hit, 2, new TGeoCombiTrans( sx3Pos.X(), sx3Pos.Y(), sx3Pos.Z(), new TGeoRotation("rotA", 0, 0, 0.))); + + geom->CloseGeometry(); + geom->SetVisLevel(4); + worldBox->Draw("ogle"); + +} + + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/Armory/ClassDet.h b/anasen_analysis_vignesh/Armory/Armory/ClassDet.h new file mode 100644 index 0000000..510cbb4 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/ClassDet.h @@ -0,0 +1,64 @@ +#ifndef ClassDet_h +#define ClassDet_h + +#include + +#define MAXMULTI 1000 + +class Det{ +public: + Det(): multi(0) {Clear(); } + + unsigned short multi; // max 65535 + unsigned short id[MAXMULTI]; + unsigned short ch[MAXMULTI]; + unsigned short e[MAXMULTI]; + unsigned long long t[MAXMULTI]; + + unsigned short sn[MAXMULTI]; + unsigned short digiCh[MAXMULTI]; + + unsigned short index[MAXMULTI]; // id * nCh + ch; + bool used[MAXMULTI]; + + void Clear(){ + multi = 0; + for( int i = 0; i < MAXMULTI; i++){ + id[i] = 0; + ch[i] = 0; + e[i] = 0; + t[i] = 0; + index[i] = 0; + sn[i] = 0; + digiCh[i] = 0; + used[i] = false; + } + } + + void Print(){ + printf("=============================== multi : %u\n", multi); + for( int i = 0; i < multi; i++) { + printf(" %3d | %2d-%-2d(%5d) %5u %15llu \n", i, id[i], ch[i], index[i], e[i], t[i]); + } + } + + void SetDetDimension(unsigned short maxID, unsigned maxCh){ + nID = maxID; + nCh = maxCh; + } + + void CalIndex(){ + for( int i = 0; i < multi; i++){ + index[i] = id[i] * nCh + ch[i] ; + } + } + +private: + + unsigned short nID; + unsigned short nCh; + +}; + + +#endif diff --git a/anasen_analysis_vignesh/Armory/Armory/ClassPC1An.h b/anasen_analysis_vignesh/Armory/Armory/ClassPC1An.h new file mode 100644 index 0000000..8e06560 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/ClassPC1An.h @@ -0,0 +1,246 @@ +#ifndef ClassPC_h +#define ClassPC_h + +#include +#include +#include +#include + +struct PCHit_1An{ + std::pair nearestWire; // anode, cathode + std::pair nearestDist; // anode, cathode + + short nextNearestWire; // cathode + double nextNearestDist; // cathode + + void Clear(){ + nearestWire.first = -1; + nearestWire.second = -1; + nearestDist.first = 999999999; + nearestDist.second = 999999999; + nextNearestWire= -1; + nextNearestDist = 999999999; + } +}; + +//!######################################################## +class PC{ // proportional wire +public: + PC(){ ClearHitInfo();}; + ~PC(){}; + + PCHit_1An GetHitInfo() const {return hitInfo;} + std::pair GetNearestID() const {return hitInfo.nearestWire;} + std::pair GetNearestDistance() const {return hitInfo.nearestDist;} + short Get2ndNearestID() const {return hitInfo.nextNearestWire;} + double Get2ndNearestDistance() const {return hitInfo.nextNearestDist;} + + TVector3 GetTrackPos() const {return trackPos;} + TVector3 GetTrackVec() const {return trackVec;} + double GetTrackTheta() const {return trackVec.Theta();} + double GetTrackPhi() const {return trackVec.Phi();} + double GetZ0(); + + int GetNumWire() const {return nWire;} + double GetDeltaAngle() const {return dAngle;} + double GetAnodeLength() const {return anodeLength;} + double GetCathodeLength() const {return cathodeLength;} + TVector3 GetAnodeDn(short id) const {return An[id].first;} + TVector3 GetAnodeUp(short id) const {return An[id].second;} + TVector3 GetCathodeDn(short id) const {return Ca[id].first;} + TVector3 GetCathodeUp(short id) const {return Ca[id].second;} + + TVector3 GetAnodneMid(short id) const {return (An[id].first + An[id].second) * 0.5; } + double GetAnodeTheta(short id) const {return (An[id].first - An[id].second).Theta();} + double GetAnodePhi(short id) const {return (An[id].first - An[id].second).Phi();} + + TVector3 GetCathodneMid(short id) const {return (Ca[id].first + Ca[id].second) * 0.5; } + double GetCathodeTheta(short id) const {return (Ca[id].first - Ca[id].second).Theta();} + double GetCathodePhi(short id) const {return (Ca[id].first - Ca[id].second).Phi();} + + void ClearHitInfo(); + void ConstructGeo(); + void FindWireID(TVector3 pos, TVector3 direction, bool verbose = false); + void CalTrack3(TVector3 sx3Pos, PCHit_1An hitInfo, double sigmaA = 0, double sigmaC = 0, bool verbose = false); + + void Print(){ + printf(" The nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nearestWire.first, + hitInfo.nearestDist.first, + hitInfo.nearestWire.second, + hitInfo.nearestDist.second); + + printf(" The 2nd nearest Cathode: %2d(%5.2f)\n", hitInfo.nextNearestWire, + hitInfo.nextNearestDist); + } + +private: + + // PCHitInfo hitInfo; + PCHit_1An hitInfo; + + TVector3 trackPos; + TVector3 trackVec; + + const int nWire = 24; + const int wireShift = 3; + const float zLen = 380; //mm + const float radiusA = 37; + const float radiusC = 43; + + double dAngle; + double anodeLength; + double cathodeLength; + + std::vector> An; // the anode wire position vector in space + std::vector> Ca; // the cathode wire position vector in space + + double Distance(TVector3 a1, TVector3 a2, TVector3 b1, TVector3 b2){ + TVector3 na = a1 - a2; + TVector3 nb = b1 - b2; + TVector3 nd = (na.Cross(nb)).Unit(); + return TMath::Abs(nd.Dot(a1-b2)); + } + +}; + +inline void PC::ClearHitInfo(){ + hitInfo.Clear(); +} + +inline void PC::ConstructGeo(){ + + An.clear(); + Ca.clear(); + + std::pair p1; // anode + std::pair q1; // cathode + + //anode and cathode start at pos-Y axis and count in right-Hand + //anode wire shift is right-hand. + //cathode wire shift is left-hand. + + for(int i = 0; i < nWire; i++ ){ + // Anode rotate right-hand + p1.first.SetXYZ( radiusA * TMath::Cos( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + radiusA * TMath::Sin( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + zLen/2); + p1.second.SetXYZ( radiusA * TMath::Cos( TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + radiusA * TMath::Sin( TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + -zLen/2); + An.push_back(p1); + + // Cathod rotate left-hand + q1.first.SetXYZ( radiusC * TMath::Cos( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + radiusC * TMath::Sin( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + zLen/2); + q1.second.SetXYZ( radiusC * TMath::Cos( TMath::TwoPi() / nWire * (i - wireShift) + TMath::PiOver2()), + radiusC * TMath::Sin( TMath::TwoPi() / nWire * (i - wireShift) + TMath::PiOver2()), + -zLen/2); + Ca.push_back(q1); + } + + dAngle = wireShift * TMath::TwoPi() / nWire; + anodeLength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusA * TMath::Sin(dAngle/2),2) ); + cathodeLength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusC * TMath::Sin(dAngle/2),2) ); +} + +inline void PC::FindWireID(TVector3 pos, TVector3 direction, bool verbose ){ + + hitInfo.Clear(); + double phi = direction.Phi(); + + for( int i = 0; i < nWire; i++){ + + double disA = 99999999; + double phiS = An[i].first.Phi() - TMath::PiOver4(); + double phiL = An[i].second.Phi() + TMath::PiOver4(); + // printf("A%2d: %f %f | %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg(), phi * TMath::RadToDeg()); + if( phi > 0 && phiS > phiL ) phiL = phiL + TMath::TwoPi(); + if( phi < 0 && phiS > phiL ) phiS = phiS - TMath::TwoPi(); + + if( phiS < phi && phi < phiL) { + disA = Distance( pos, pos + direction, An[i].first, An[i].second); + if( disA < hitInfo.nearestDist.first ){ + hitInfo.nearestDist.first = disA; + hitInfo.nearestWire.first = i; + } + } + + double disC = 99999999; + phiS = Ca[i].second.Phi()- TMath::PiOver4(); + phiL = Ca[i].first.Phi() + TMath::PiOver4(); + // printf("C%2d: %f %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg()); + if( phi > 0 && phiS > phiL ) phiL = phiL + TMath::TwoPi(); + if( phi < 0 && phiS > phiL ) phiS = phiS - TMath::TwoPi(); + + if(phiS < phi && phi < phiL) { + disC = Distance( pos, pos + direction, Ca[i].first, Ca[i].second); + if( disC < hitInfo.nearestDist.second ){ + hitInfo.nearestDist.second = disC; + hitInfo.nearestWire.second = i; + } + } + + if(verbose) printf(" %2d | %8.2f, %8.2f\n", i, disA, disC); + } + + short cathode1 = hitInfo.nearestWire.second; + short ccc1 = cathode1 - 1; if( ccc1 < 0 ) ccc1 += nWire; + short ccc2 = (cathode1 + 1) % nWire; + + double haha1 = Distance( pos, pos + direction, Ca[ccc1].first, Ca[ccc1].second); + double haha2 = Distance( pos, pos + direction, Ca[ccc2].first, Ca[ccc2].second); + if( haha1 < haha2){ + hitInfo.nextNearestWire = ccc1; + hitInfo.nextNearestDist = haha1; + }else{ + hitInfo.nextNearestWire = ccc2; + hitInfo.nextNearestDist= haha2; + } + + if( verbose ) Print(); +} + + +inline void PC::CalTrack3(TVector3 sx3Pos, PCHit_1An hitInfo, double sigmaA, double sigmaC, bool verbose){ + + trackPos = sx3Pos; + + double p1 = TMath::Abs(hitInfo.nearestDist.first + gRandom->Gaus(0, sigmaA)); + short anodeID1 = hitInfo.nearestWire.first; + + double q1 = TMath::Abs(hitInfo.nearestDist.second + gRandom->Gaus(0, sigmaC)); + double q2 = TMath::Abs(hitInfo.nextNearestDist+ gRandom->Gaus(0, sigmaC)); + double fracC = q1 / (q1 + q2); + short cathodeID1 = hitInfo.nearestWire.second; + short cathodeID2 = hitInfo.nextNearestWire; + TVector3 shiftC1 = (Ca[cathodeID2].first - Ca[cathodeID1].first) * fracC; + TVector3 shiftC2 = (Ca[cathodeID2].second - Ca[cathodeID1].second) * fracC; + + TVector3 a1 = An[anodeID1].first; + + TVector3 c1 = Ca[cathodeID1].first + shiftC1; + TVector3 c2 = Ca[cathodeID1].second + shiftC2; + + TVector3 n1 = (sx3Pos - a1).Unit(); + TVector3 n2 = (c1 - c2).Cross((sx3Pos - c2)).Unit(); + + // if the handiness of anode and cathode revered, it should be n2 cross n1 + trackVec = (n2.Cross(n1)).Unit(); + + if( verbose ) printf("Theta, Phi = %f, %f \n", trackVec.Theta() *TMath::RadToDeg(), trackVec.Phi()*TMath::RadToDeg()); + +} + +inline double PC::GetZ0(){ + + double x = trackPos.X(); + double y = trackPos.Y(); + double rho = TMath::Sqrt(x*x + y*y); + double theta = trackVec.Theta(); + + return trackPos.Z() - rho / TMath::Tan(theta); + +} + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/Armory/ClassPW.h b/anasen_analysis_vignesh/Armory/Armory/ClassPW.h new file mode 100644 index 0000000..92e015c --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/ClassPW.h @@ -0,0 +1,315 @@ +#ifndef ClassPW_h +#define ClassPW_h + +#include +#include +#include +#include + +struct PWHitInfo +{ + std::pair nearestWire; // anode, cathode + std::pair nearestDist; // anode, cathode + + std::pair nextNearestWire; // anode, cathode + std::pair nextNearestDist; // anode, cathode + + void Clear() + { + nearestWire.first = -1; + nearestWire.second = -1; + nearestDist.first = 999999999; + nearestDist.second = 999999999; + nextNearestWire.first = -1; + nextNearestWire.second = -1; + nextNearestDist.first = 999999999; + nextNearestDist.second = 999999999; + } +}; + +struct Coord +{ + float x, y, z; + Coord() : x(0), y(0), z(0) {} + Coord(const TVector3 &vec) + { + x = vec.X(); // TVector3's X() returns the x-coordinate + y = vec.Y(); // TVector3's Y() returns the y-coordinate + z = vec.Z(); // TVector3's Z() returns the z-coordinate + } +}; + +//! ######################################################## +class PW +{ // proportional wire +public: + PW() { ClearHitInfo(); }; + ~PW() {}; + + PWHitInfo GetHitInfo() const { return hitInfo; } + std::pair GetNearestID() const { return hitInfo.nearestWire; } + std::pair GetNearestDistance() const { return hitInfo.nearestDist; } + std::pair Get2ndNearestID() const { return hitInfo.nextNearestWire; } + std::pair Get2ndNearestDistance() const { return hitInfo.nextNearestDist; } + + std::vector> An; // the anode wire position vector in space + std::vector> Ca; // the cathode wire position vector in space + + TVector3 GetTrackPos() const { return trackPos; } + TVector3 GetTrackVec() const { return trackVec; } + double GetTrackTheta() const { return trackVec.Theta(); } + double GetTrackPhi() const { return trackVec.Phi(); } + double GetZ0(); + + int GetNumWire() const { return nWire; } + double GetDeltaAngle() const { return dAngle; } + double GetAnodeLength() const { return anodeLength; } + double GetCathodeLength() const { return cathodeLength; } + TVector3 GetAnodeDn(short id) const { return An[id].first; } + TVector3 GetAnodeUp(short id) const { return An[id].second; } + TVector3 GetCathodeDn(short id) const { return Ca[id].first; } + TVector3 GetCathodeUp(short id) const { return Ca[id].second; } + + TVector3 GetAnodneMid(short id) const { return (An[id].first + An[id].second) * 0.5; } + double GetAnodeTheta(short id) const { return (An[id].first - An[id].second).Theta(); } + double GetAnodePhi(short id) const { return (An[id].first - An[id].second).Phi(); } + + TVector3 GetCathodneMid(short id) const { return (Ca[id].first + Ca[id].second) * 0.5; } + double GetCathodeTheta(short id) const { return (Ca[id].first - Ca[id].second).Theta(); } + double GetCathodePhi(short id) const { return (Ca[id].first - Ca[id].second).Phi(); } + + void ClearHitInfo(); + void ConstructGeo(); + void FindWireID(TVector3 pos, TVector3 direction, bool verbose = false); + void CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose = false); + void CalTrack2(TVector3 sx3Pos, TVector3 anodeInt, bool verbose = false); + + void Print() + { + printf(" The nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nearestWire.first, + hitInfo.nearestDist.first, + hitInfo.nearestWire.second, + hitInfo.nearestDist.second); + + printf(" The 2nd nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nextNearestWire.first, + hitInfo.nextNearestDist.first, + hitInfo.nextNearestWire.second, + hitInfo.nextNearestDist.second); + } + +private: + PWHitInfo hitInfo; + + TVector3 trackPos; + TVector3 trackVec; + + const int nWire = 24; + const int wireShift = 3; + const float zLen = 380; // mm + const float radiusA = 37; + const float radiusC = 43; + + double dAngle; + double anodeLength; + double cathodeLength; + + // std::vector> An; // the anode wire position vector in space + // std::vector> Ca; // the cathode wire position vector in space + + double Distance(TVector3 a1, TVector3 a2, TVector3 b1, TVector3 b2) + { + TVector3 na = a1 - a2; + TVector3 nb = b1 - b2; + TVector3 nd = (na.Cross(nb)).Unit(); + return TMath::Abs(nd.Dot(a1 - b2)); + } +}; + +inline void PW::ClearHitInfo() +{ + hitInfo.Clear(); +} + +inline void PW::ConstructGeo() +{ + + An.clear(); + Ca.clear(); + + std::pair p1; // anode + std::pair q1; // cathode + + // anode and cathode start at pos-Y axis and count in right-Hand + // anode wire shift is right-hand. + // cathode wire shift is left-hand. + + for (int i = 0; i < nWire; i++) + { + // Anode rotate right-hand + p1.first.SetXYZ(radiusA * TMath::Cos(TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + radiusA * TMath::Sin(TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + zLen / 2); + p1.second.SetXYZ(radiusA * TMath::Cos(TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + radiusA * TMath::Sin(TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + -zLen / 2); + An.push_back(p1); + + // Cathod rotate left-hand with the 3 wire offset accounted for (+1 from the calculated offset from the PC coincidence spectrum) + q1.first.SetXYZ(radiusC * TMath::Cos(TMath::TwoPi() / nWire * (i + wireShift + 1) + TMath::PiOver2()), + radiusC * TMath::Sin(TMath::TwoPi() / nWire * (i + wireShift + 1) + TMath::PiOver2()), + zLen / 2); + q1.second.SetXYZ(radiusC * TMath::Cos(TMath::TwoPi() / nWire * (i + 1) + TMath::PiOver2()), + radiusC * TMath::Sin(TMath::TwoPi() / nWire * (i + 1) + TMath::PiOver2()), + -zLen / 2); + Ca.push_back(q1); + } + // correcting for the fact that the order of the cathode wires is reversed + std::reverse(Ca.begin(), Ca.end()); + // adjusting for the 3 wire offset, the rbegin and rend are used as the rotation of the wires is done in the opposite direction i.e. 1,2,3 -> 3,1,2 + // NOT NECESSARY ANY MORE, HAS BEEN IMCORPORATED INTO THE WIREOFFSET IN THE BEGINNING + // std::rotate(Ca.rbegin(), Ca.rbegin() + 4, Ca.rend()); + + dAngle = wireShift * TMath::TwoPi() / nWire; + anodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusA * TMath::Sin(dAngle / 2), 2)); + cathodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusC * TMath::Sin(dAngle / 2), 2)); +} + +inline void PW::FindWireID(TVector3 pos, TVector3 direction, bool verbose) +{ + + hitInfo.Clear(); + double phi = direction.Phi(); + + for (int i = 0; i < nWire; i++) + { + + double disA = 99999999; + double phiS = An[i].first.Phi() - TMath::PiOver4(); + double phiL = An[i].second.Phi() + TMath::PiOver4(); + // printf("A%2d: %f %f | %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg(), phi * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disA = Distance(pos, pos + direction, An[i].first, An[i].second); + if (disA < hitInfo.nearestDist.first) + { + hitInfo.nearestDist.first = disA; + hitInfo.nearestWire.first = i; + } + } + + double disC = 99999999; + phiS = Ca[i].second.Phi() - TMath::PiOver4(); + phiL = Ca[i].first.Phi() + TMath::PiOver4(); + // printf("C%2d: %f %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disC = Distance(pos, pos + direction, Ca[i].first, Ca[i].second); + if (disC < hitInfo.nearestDist.second) + { + hitInfo.nearestDist.second = disC; + hitInfo.nearestWire.second = i; + } + } + + if (verbose) + printf(" %2d | %8.2f, %8.2f\n", i, disA, disC); + } + + //==== find the 2nd nearest wire + short anode1 = hitInfo.nearestWire.first; + short aaa1 = anode1 - 1; + if (aaa1 < 0) + aaa1 += nWire; + short aaa2 = (anode1 + 1) % nWire; + + double haha1 = Distance(pos, pos + direction, An[aaa1].first, An[aaa1].second); + double haha2 = Distance(pos, pos + direction, An[aaa2].first, An[aaa2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.first = aaa1; + hitInfo.nextNearestDist.first = haha1; + } + else + { + hitInfo.nextNearestWire.first = aaa2; + hitInfo.nextNearestDist.first = haha2; + } + + short cathode1 = hitInfo.nearestWire.second; + short ccc1 = cathode1 - 1; + if (ccc1 < 0) + ccc1 += nWire; + short ccc2 = (cathode1 + 1) % nWire; + + haha1 = Distance(pos, pos + direction, Ca[ccc1].first, Ca[ccc1].second); + haha2 = Distance(pos, pos + direction, Ca[ccc2].first, Ca[ccc2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.second = ccc1; + hitInfo.nextNearestDist.second = haha1; + } + else + { + hitInfo.nextNearestWire.second = ccc2; + hitInfo.nextNearestDist.second = haha2; + } + + if (verbose) + Print(); +} + +inline void PW::CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose) +{ + + trackPos = sx3Pos; + + TVector3 n1 = (An[anodeID].first - An[anodeID].second).Cross((sx3Pos - An[anodeID].second)).Unit(); + TVector3 n2 = (Ca[cathodeID].first - Ca[cathodeID].second).Cross((sx3Pos - Ca[cathodeID].second)).Unit(); + + // if the handiness of anode and cathode revered, it should be n2 cross n1 + trackVec = (n2.Cross(n1)).Unit(); + + if (verbose) + printf("Theta, Phi = %f, %f \n", trackVec.Theta() * TMath::RadToDeg(), trackVec.Phi() * TMath::RadToDeg()); +} + + +inline void PW::CalTrack2(TVector3 siPos, TVector3 anodeInt, bool verbose) +{ + + double mx, my; + double z; + mx = siPos.X() / (siPos.X() - anodeInt.X()); + my = siPos.Y() / (siPos.Y() - anodeInt.Y()); + z=siPos.Z() + mx * (anodeInt.Z() - siPos.Z()); + // if (mx == my) + { + trackVec=TVector3(0,0,z); + } + + if (verbose) + printf("X slope = %f and Y slope = %f \n", mx, my); +} + +inline double PW::GetZ0() +{ + + double x = trackPos.X(); + double y = trackPos.Y(); + double rho = TMath::Sqrt(x * x + y * y); + double theta = trackVec.Theta(); + + return trackVec.Z(); +} + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/Armory/ClassSX3.h b/anasen_analysis_vignesh/Armory/Armory/ClassSX3.h new file mode 100644 index 0000000..3586292 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/ClassSX3.h @@ -0,0 +1,257 @@ +#ifndef ClassSX3_h +#define ClassSX3_h + +#include +#include +#include +#include + +class SX3{ +public: + SX3(){Clear();}; + ~SX3(){} + + short GetID() const {return id;} + short GetChUp() const {return chUp;} + short GetChDn() const {return chDn;} + short GetChBk() const {return chBk;} + + TVector3 GetHitPos() const {return hitPos;} + TVector3 GetHitPosWithSigma(double sigmaY_mm, double sigmaZ_mm); + + double GetZFrac() const {return zFrac;} // range from -0.5 to 0.5 + + void Clear(); + void ConstructGeo(); + void FindSX3Pos(TVector3 pos, TVector3 direction, bool verbose = false); + void CalSX3Pos(unsigned short ID, unsigned short chUp, unsigned short chDown, unsigned short chBack, float eUp, float eDown); + + double GetNumDet() const {return numDet;} + double GetWidth() const {return width;} + double GetLength() const {return length;} + TVector3 GetDnL(short id) const {return SDn[id].first; } // lower strip ID + TVector3 GetDnH(short id) const {return SDn[id].second; } // higher strip ID + TVector3 GetUpL(short id) const {return SUp[id].first; } // lower strip ID + TVector3 GetUpH(short id) const {return SUp[id].second; } // higher strip ID + + TVector3 GetDnMid(short id) const { return (SDn[id].first + SDn[id].second)*0.5;} + TVector3 GetUpMid(short id) const { return (SUp[id].first + SUp[id].second)*0.5;} + + double GetDetPhi(short id) const { return (SUp[id].second - SUp[id].first).Phi();} + + void Print(){ + if( id == -1 ){ + printf("Did not hit any SX3.\n"); + }else{ + printf("ID: %d, U,D,B: %d %d %d| zFrac : %.2f\n", id, chUp, chDn, chBk, zFrac); + printf("Hit Pos: %.2f, %.2f, %.2f\n", hitPos.X(), hitPos.Y(), hitPos.Z()); + } + } + + // void CalZFrac(){ + // zFrac = (eUp - eDn)/(eUp + eDn); + // } + +private: + + const int numDet = 12; + const float radius = 88; + const float width = 40; + const float length = 75; + const float gap = 46; + + short id; // -1 when no hit + short chUp; + short chDn; + short chBk; + + double zFrac; // from +1 (downstream) to -1 (upstream) + + double eUp; + double eDn; + double eBk; + + TVector3 hitPos; + + std::vector> SDn; // coners of the SX3 0-11, z = mid point + std::vector> SUp; // coners of the SX3 12-23, z = mid point + std::vector SNorml; // normal of the SX3 (outward) + + + std::pair Intersect(TVector3 p1, TVector3 p2, TVector3 q1, TVector3 q2, bool verbose){ + + //see https://nukephysik101.wordpress.com/2023/12/30/intersect-between-2-line-segments/ + //zero all z-component + TVector3 a0 = p1; a0.SetZ(0); + TVector3 a1 = p2; a1.SetZ(0); + + TVector3 b0 = q1; b0.SetZ(0); + TVector3 b1 = q2; b1.SetZ(0); + + double A = ((b0-b1).Cross(a0-a1)).Mag(); + + double h = ((b0-a0).Cross(b1-a0)).Z()/ A; + double k = ((a1-b0).Cross(a0-b0)).Z()/ A; + + if( verbose ) printf(" ----h, k : %f, %f\n", h, k); + + return std::pair(h,k); + } + +}; + +inline void SX3::Clear(){ + id = -1; + chUp = -1; + chDn = -1; + chBk = -1; + zFrac = TMath::QuietNaN(); + + eUp = TMath::QuietNaN(); + eDn = TMath::QuietNaN(); + eBk = TMath::QuietNaN(); + + SDn.clear(); + SUp.clear(); +} + +inline void SX3::ConstructGeo(){ + TVector3 sa, sb, sc, sn; + + for(int i = 0; i < numDet; i++){ + sa.SetXYZ( radius, -width/2, gap/2 + length/2 ); + sb.SetXYZ( radius, width/2, gap/2 + length/2 ); + + double rot = TMath::TwoPi() / numDet * (i - 0.5) - TMath::PiOver2(); + + sa.RotateZ( rot ); + sb.RotateZ( rot ); + SDn.push_back(std::pair(sa,sb)); + + sc.SetXYZ( radius, -width/2, gap/2 ); + sc.RotateZ( rot ); + + sn = ((sc-sa).Cross(sb-sa)).Unit(); + SNorml.push_back(sn); + + sa.SetXYZ( radius, -width/2, -gap/2 - length/2 ); + sb.SetXYZ( radius, width/2, -gap/2 - length/2 ); + + sa.RotateZ( rot ); + sb.RotateZ( rot ); + SUp.push_back(std::pair(sa,sb)); + } +} + + +inline void SX3::FindSX3Pos(TVector3 pos, TVector3 direction, bool verbose){ + + id = -1; + for( int i = 0 ; i < numDet; i++){ + + if(verbose) printf(" %d ", i); + std::pair frac = Intersect( pos, pos + direction, SDn[i].first, SDn[i].second, verbose); + + + if( frac.second < 0 || frac.second > 1 ) continue; + hitPos = pos + frac.first * direction; + + double dis = hitPos.Dot(SNorml[i]); + + if(verbose) { + printf("reduced distance : %f\n", dis); + printf(" %d*", (i+1)%numDet); + Intersect( pos, pos + direction, SDn[(i+1)%numDet].first, SDn[(i+1)%numDet].second, verbose); + } + + if( TMath::Abs(dis - radius) > 0.1 ) continue; + + chDn = 2 * TMath::Floor(frac.second * 4); + chUp = chDn + 1; + + double zPos = hitPos.Z(); + if( (gap/2 < zPos && zPos < gap/2 + length ) || (-gap/2 - length < zPos && zPos < -gap/2 ) ){ + + id = zPos > 0 ? i : i + 12; + + zFrac = zPos > 0 ? (zPos - gap/2. - length/2.)/length : (zPos - ( - gap/2. - length/2.) )/length ; + + chBk = TMath::Floor( (zFrac + 0.5) * 4 ) + 8; + + if( verbose) Print(); + return ; + + }else{ + if( verbose ) printf(" zPos out of sensitive region\n"); + } + } + + if( verbose) Print(); +} + +inline TVector3 SX3::GetHitPosWithSigma(double sigmaY_mm, double sigmaZ_mm){ + + double phi = SNorml[id%numDet].Phi(); + + TVector3 haha = hitPos; + haha.RotateZ(-phi); + + double y = haha.Y() + gRandom->Gaus(0, sigmaY_mm); + if( sigmaY_mm < 0 ){ + double deltaW = width/4; + y = TMath::Floor((haha.Y()-deltaW)/deltaW)*deltaW + deltaW*1.5; // when ever land on each strip, set the position to be center of the strip. + if( y >= 25 ) y = 15; + } + + double z = haha.Z() + gRandom->Gaus(0, sigmaZ_mm); + if( sigmaZ_mm < 0 ){ + haha.Z(); + double delta = length/4; + int sign = z > 0 ? 1 : -1; + z = TMath::Floor( (abs(z)-gap/2)/delta )*delta + 0.5 * delta + gap/2; + if( z >= 107.375 ) z = 88.625; + z = sign * z; + } + + haha.SetY(y); + haha.SetZ(z); + haha.RotateZ(phi); + + return haha; + +} + + +inline void SX3::CalSX3Pos(unsigned short ID, unsigned short chUp, unsigned short chDown, unsigned short chBack, float eUp, float eDown){ + + hitPos.Clear(); + + + if( (chUp - chDown) != 1 || (chDown % 2) != 0) return ; + + int reducedID = ID % numDet; + + TVector3 sa, sb; + + if( ID < numDet ){ //down + sa = SDn[reducedID].second; + sb = SDn[reducedID].first; + }else{ + sa = SUp[reducedID].second; + sb = SUp[reducedID].first; + } + + hitPos.SetX( (sb.X() - sa.X()) * chUp/8 + sa.X()); + hitPos.SetY( (sb.Y() - sa.Y()) * chUp/8 + sa.Y()); + + if( eUp == 0 || eDown == 0 ){ + hitPos.SetZ( sa.Z() + (2*(chBk - 7)-1) * length / 8 ); + }else{ + double frac = (eUp - eDown)/(eUp + eDown); // from +1 (downstream) to -1 (upstream) + double zPos = sa.Z() + length * frac/2; + hitPos.SetZ( zPos ); + } + +} + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/Armory/ClassTransfer.h b/anasen_analysis_vignesh/Armory/Armory/ClassTransfer.h new file mode 100644 index 0000000..c12c43f --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/ClassTransfer.h @@ -0,0 +1,468 @@ +#ifndef ClassTransfer_h +#define ClassTransfer_h + +#include "TBenchmark.h" +#include "TLorentzVector.h" +#include "TVector3.h" +#include "TMath.h" +#include "TFile.h" +#include "TTree.h" +#include "TRandom.h" +#include "TMacro.h" +#include "TGraph.h" +#include +#include + +#include "Isotope.h" + +class ReactionConfig{ + +public: + + ReactionConfig(){} + ~ReactionConfig(){} + + int beamA, beamZ; + int targetA, targetZ; + int recoilLightA, recoilLightZ; + int recoilHeavyA, recoilHeavyZ; + + float beamEnergy; ///MeV/u + float beamEnergySigma; ///beam-energy_sigma_in_MeV/u + float beamAngle; ///beam-angle_in_mrad + float beamAngleSigma; ///beam-emittance_in_mrad + float beamX; ///x_offset_of_Beam_in_mm + float beamY; ///y_offset_of_Beam_in_mm + int numEvents; ///number_of_Event_being_generated + bool isTargetScattering; ///isTargetScattering + float targetDensity; ///target_density_in_g/cm3 + float targetThickness; ///targetThickness_in_cm + std::string beamStoppingPowerFile; ///stopping_power_for_beam + std::string recoilLightStoppingPowerFile; ///stopping_power_for_light_recoil + std::string recoilHeavyStoppingPowerFile; ///stopping_power_for_heavy_recoil + bool isDecay; ///isDacay + int heavyDecayA; ///decayNucleus_A + int heavyDecayZ; ///decayNucleus_Z + bool isRedo; ///isReDo + std::vector beamEx; ///excitation_energy_of_A[MeV] + + + void SetReaction(int beamA, int beamZ, + int targetA, int targetZ, + int recoilA, int recoilZ, float beamEnergy_AMeV){ + this->beamA = beamA; + this->beamZ = beamZ; + this->targetA = targetA; + this->targetZ = targetZ; + this->recoilLightA = recoilA; + this->recoilLightZ = recoilZ; + + recoilHeavyA = this->beamA + this->targetA - recoilLightA; + recoilHeavyZ = this->beamZ + this->targetZ - recoilLightZ; + + } + + void LoadReactionConfig(TMacro * macro){ + + if( macro == NULL ) return ; + + int numLine = macro->GetListOfLines()->GetSize(); + + for( int i = 0; i < numLine; i ++){ + + std::vector str = SplitStr(macro->GetListOfLines()->At(i)->GetName(), " "); + + ///printf("%d | %s\n", i, str[0].c_str()); + + if( str[0].find_first_of("#") == 0 ) break; + + if( i == 0 ) beamA = atoi(str[0].c_str()); + if( i == 1 ) beamZ = atoi(str[0].c_str()); + if( i == 2 ) targetA = atoi(str[0].c_str()); + if( i == 3 ) targetZ = atoi(str[0].c_str()); + if( i == 4 ) recoilLightA = atoi(str[0].c_str()); + if( i == 5 ) recoilLightZ = atoi(str[0].c_str()); + if( i == 6 ) beamEnergy = atof(str[0].c_str()); + if( i == 7 ) beamEnergySigma = atof(str[0].c_str()); + if( i == 8 ) beamAngle = atof(str[0].c_str()); + if( i == 9 ) beamAngleSigma = atof(str[0].c_str()); + if( i == 10 ) beamX = atof(str[0].c_str()); + if( i == 11 ) beamY = atof(str[0].c_str()); + if( i == 12 ) numEvents = atoi(str[0].c_str()); + if( i == 13 ) { + if( str[0].compare("false") == 0 ) isTargetScattering = false; + if( str[0].compare("true") == 0 ) isTargetScattering = true; + } + if( i == 14 ) targetDensity = atof(str[0].c_str()); + if( i == 15 ) targetThickness = atof(str[0].c_str()); + if( i == 16 ) beamStoppingPowerFile = str[0]; + if( i == 17 ) recoilLightStoppingPowerFile = str[0]; + if( i == 18 ) recoilHeavyStoppingPowerFile = str[0]; + if( i == 19 ) { + if( str[0].compare("false") == 0 ) isDecay = false; + if( str[0].compare("true") == 0 ) isDecay = true; + } + if( i == 20 ) heavyDecayA = atoi(str[0].c_str()); + if( i == 21 ) heavyDecayZ = atoi(str[0].c_str()); + if( i == 22 ) { + if( str[0].compare("false") == 0 ) isRedo = false; + if( str[0].compare("true" ) == 0 ) isRedo = true; + } + + if( i >= 23) { + beamEx.push_back( atof(str[0].c_str()) ); + } + } + + recoilHeavyA = beamA + targetA - recoilLightA; + recoilHeavyZ = beamZ + targetZ - recoilLightZ; + + } + + void PrintReactionConfig(){ + + printf("=====================================================\n"); + printf(" beam : A = %3d, Z = %2d \n", beamA, beamZ); + printf(" target : A = %3d, Z = %2d \n", targetA, targetZ); + printf(" light : A = %3d, Z = %2d \n", recoilLightA, recoilLightZ); + + printf(" beam Energy : %.2f +- %.2f MeV/u, dE/E = %5.2f %%\n", beamEnergy, beamEnergySigma, beamEnergySigma/beamEnergy); + printf(" Angle : %.2f +- %.2f mrad\n", beamAngle, beamAngleSigma); + printf(" offset : (x,y) = (%.2f, %.2f) mmm \n", beamX, beamY); + + printf("##### number of Simulation Events : %d \n", numEvents); + + printf(" is target scattering : %s \n", isTargetScattering ? "Yes" : "No"); + + if(isTargetScattering){ + printf(" target density : %.f g/cm3\n", targetDensity); + printf(" thickness : %.f cm\n", targetThickness); + printf(" beam stopping file : %s \n", beamStoppingPowerFile.c_str()); + printf(" recoil light stopping file : %s \n", recoilLightStoppingPowerFile.c_str()); + printf(" recoil heavy stopping file : %s \n", recoilHeavyStoppingPowerFile.c_str()); + } + + printf(" is simulate decay : %s \n", isDecay ? "Yes" : "No"); + if( isDecay ){ + printf(" heavy decay : A = %d, Z = %d \n", heavyDecayA, heavyDecayZ); + } + printf(" is Redo until hit array : %s \n", isRedo ? "Yes" : "No"); + + printf(" beam Ex : %.2f MeV \n", beamEx[0]); + for( int i = 1; i < (int) beamEx.size(); i++){ + printf(" %.2f MeV \n", beamEx[i]); + } + + printf("=====================================================\n"); + + } + +}; + +//======================================================= +//####################################################### +// Class for Transfer Reaction +// reaction notation A(a,b)B +// A = incident particle +// a = target +// b = light scattered particle +// B = heavy scattered particle +//======================================================= +class TransferReaction { +public: + TransferReaction(); + ~TransferReaction(); + + void SetA(int A, int Z, double Ex); + void Seta(int A, int Z); + void Setb(int A, int Z); + void SetB(int A, int Z); + void SetIncidentEnergyAngle(double KEA, double theta, double phi); + void SetExA(double Ex); + void SetExB(double Ex); + void SetReactionFromFile(string settingFile); + + TString GetReactionName(); + TString GetReactionName_Latex(); + + ReactionConfig GetRectionConfig() { return reaction;} + + double GetMass_A(){return mA + ExA;} + double GetMass_a(){return ma;} + double GetMass_b(){return mb;} + double GetMass_B(){return mB + ExB;} + + double GetCMTotalKE() {return Etot - mA - ma;} + double GetQValue() {return mA + ExA + ma - mb - mB - ExB;} + double GetMaxExB() {return Etot - mb - mB;} + + TLorentzVector GetPA(){return PA;} + TLorentzVector GetPa(){return Pa;} + TLorentzVector GetPb(){return Pb;} + TLorentzVector GetPB(){return PB;} + + void CalReactionConstant(); + + TLorentzVector * Event(double thetaCM, double phiCM); + + double GetEx(){return Ex;} + double GetThetaCM(){return thetaCM;} + + double GetMomentumbCM() {return p;} + double GetReactionBeta() {return beta;} + double GetReactionGamma() {return gamma;} + double GetCMTotalEnergy() {return Etot;} + +private: + + ReactionConfig reaction; + + string nameA, namea, nameb, nameB; + double thetaIN, phiIN; + double mA, ma, mb, mB; + + double TA, T; // TA = KE of A pre u, T = total energy + double ExA, ExB; + double Ex, thetaCM; //calculated Ex using inverse mapping from e and z to thetaCM + + bool isReady; + bool isBSet; + + double k; // CM Boost momentum + double beta, gamma; //CM boost beta + double Etot; + double p; // CM frame momentum of b, B + + TLorentzVector PA, Pa, Pb, PB; + + TString format(TString name); + +}; + +TransferReaction::TransferReaction(){ + + thetaIN = 0.; + phiIN = 0.; + SetA(24, 12, 0); + Seta(4,2); + Setb(1,1); + SetB(27,13); + TA = 2.5; + T = TA * reaction.beamA; + + ExA = 0; + ExB = 0; + + Ex = TMath::QuietNaN(); + thetaCM = TMath::QuietNaN(); + + CalReactionConstant(); + + TLorentzVector temp (0,0,0,0); + PA = temp; + Pa = temp; + Pb = temp; + PB = temp; + +} + +TransferReaction::~TransferReaction(){ + +} + +void TransferReaction::SetA(int A, int Z, double Ex = 0){ + Isotope temp (A, Z); + mA = temp.Mass; + reaction.beamA = A; + reaction.beamZ = Z; + ExA = Ex; + nameA = temp.Name; + isReady = false; + isBSet = true; + +} + +void TransferReaction::Seta(int A, int Z){ + Isotope temp (A, Z); + ma = temp.Mass; + reaction.targetA = A; + reaction.targetZ = Z; + namea = temp.Name; + isReady = false; + isBSet = false; +} + +void TransferReaction::Setb(int A, int Z){ + Isotope temp (A, Z); + mb = temp.Mass; + reaction.recoilLightA = A; + reaction.recoilLightZ = Z; + nameb = temp.Name; + isReady = false; + isBSet = false; +} +void TransferReaction::SetB(int A, int Z){ + Isotope temp (A, Z); + mB = temp.Mass; + reaction.recoilHeavyA = A; + reaction.recoilHeavyZ = Z; + nameB = temp.Name; + isReady = false; + isBSet = true; +} + +void TransferReaction::SetIncidentEnergyAngle(double KEA, double theta, double phi){ + this->TA = KEA; + this->T = TA * reaction.beamA; + this->thetaIN = theta; + this->phiIN = phi; + isReady = false; +} + +void TransferReaction::SetExA(double Ex){ + this->ExA = Ex; + isReady = false; +} + +void TransferReaction::SetExB(double Ex){ + this->ExB = Ex; + isReady = false; +} + +void TransferReaction::SetReactionFromFile(string settingFile){ + + TMacro * haha = new TMacro(); + if( haha->ReadFile(settingFile.c_str()) > 0 ) { + reaction.LoadReactionConfig(haha); + + SetA(reaction.beamA, reaction.beamZ); + Seta(reaction.targetA, reaction.targetZ); + Setb(reaction.recoilLightA, reaction.recoilLightZ); + SetB(reaction.recoilHeavyA, reaction.recoilHeavyZ); + + SetIncidentEnergyAngle(reaction.beamEnergy, 0, 0); + CalReactionConstant(); + }else{ + + printf("cannot read file %s.\n", settingFile.c_str()); + isReady = false; + } + +} + +TString TransferReaction::GetReactionName(){ + TString rName; + rName.Form("%s(%s,%s)%s", nameA.c_str(), namea.c_str(), nameb.c_str(), nameB.c_str()); + return rName; +} + +TString TransferReaction::format(TString name){ + if( name.IsAlpha() ) return name; + int len = name.Length(); + TString temp = name; + TString temp2 = name; + if( temp.Remove(0, len-2).IsAlpha()){ + temp2.Remove(len-2); + }else{ + temp = name; + temp.Remove(0, len-1); + temp2.Remove(len-1); + } + return "^{"+temp2+"}"+temp; +} + +TString TransferReaction::GetReactionName_Latex(){ + TString rName; + rName.Form("%s(%s,%s)%s", format(nameA).Data(), format(namea).Data(), format(nameb).Data(), format(nameB).Data()); + return rName; +} + +void TransferReaction::CalReactionConstant(){ + if( !isBSet){ + reaction.recoilHeavyA = reaction.beamA + reaction.targetA - reaction.recoilLightA; + reaction.recoilHeavyZ = reaction.beamZ + reaction.targetZ - reaction.recoilLightZ; + Isotope temp (reaction.recoilHeavyA, reaction.recoilHeavyZ); + mB = temp.Mass; + isBSet = true; + } + + k = TMath::Sqrt(TMath::Power(mA + ExA + T, 2) - (mA + ExA) * (mA + ExA)); + beta = k / (mA + ExA + ma + T); + gamma = 1 / TMath::Sqrt(1- beta * beta); + Etot = TMath::Sqrt(TMath::Power(mA + ExA + ma + T,2) - k * k); + p = TMath::Sqrt( (Etot*Etot - TMath::Power(mb + mB + ExB,2)) * (Etot*Etot - TMath::Power(mb - mB - ExB,2)) ) / 2 / Etot; + + PA.SetXYZM(0, 0, k, mA + ExA); + PA.RotateY(thetaIN); + PA.RotateZ(phiIN); + + Pa.SetXYZM(0,0,0,ma); + + isReady = true; +} + +TLorentzVector * TransferReaction::Event(double thetaCM, double phiCM) +{ + if( isReady == false ){ + CalReactionConstant(); + } + + //TLorentzVector Pa(0, 0, 0, ma); + + //---- to CM frame + TLorentzVector Pc = PA + Pa; + TVector3 b = Pc.BoostVector(); + + TVector3 vb(0,0,0); + + if( b.Mag() > 0 ){ + TVector3 v0 (0,0,0); + TVector3 nb = v0 - b; + + TLorentzVector PAc = PA; + PAc.Boost(nb); + TVector3 vA = PAc.Vect(); + + TLorentzVector Pac = Pa; + Pac.Boost(nb); + TVector3 va = Pac.Vect(); + + //--- construct vb + vb = va; + vb.SetMag(p); + + TVector3 ub = vb.Orthogonal(); + vb.Rotate(thetaCM, ub); + vb.Rotate(phiCM + TMath::PiOver2(), va); // somehow, the calculation turn the vector 90 degree. + //vb.Rotate(phiCM , va); // somehow, the calculation turn the vector 90 degree. + } + + //--- from Pb + TLorentzVector Pbc; + Pbc.SetVectM(vb, mb); + + //--- from PB + TLorentzVector PBc; + //PBc.SetVectM(vB, mB + ExB); + PBc.SetVectM(-vb, mB + ExB); + + //---- to Lab Frame + TLorentzVector Pb = Pbc; + Pb.Boost(b); + TLorentzVector PB = PBc; + PB.Boost(b); + + TLorentzVector * output = new TLorentzVector[4]; + output[0] = PA; + output[1] = Pa; + output[2] = Pb; + output[3] = PB; + + this->Pb = Pb; + this->PB = PB; + + + return output; +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/Armory/HistPlotter.h b/anasen_analysis_vignesh/Armory/Armory/HistPlotter.h new file mode 100644 index 0000000..8bba450 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/HistPlotter.h @@ -0,0 +1,414 @@ +#ifndef HISTPLOTTER_H +#define HISTPLOTTER_H +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +class HistPlotter { +private: + long long barrier_count, barrier_limit; //meant to keep track of how often to call FillN() on histograms + enum {TFILE, TMEMFILE} filetype; + std::unordered_map oMap; //!< Maps std::string to all TH1, TH2 objects in the class + std::unordered_map cutsMap; //!< Maps std::string to TCutG objects held by the class + std::set folderList; //!< List of all folder names used to nest objects + std::unordered_map foldersForObjects; //!< Map that returns the folder corresponding to the object whose pointer is specified + TFile *ofile=nullptr; //!< TFile pointer for the output file + TMemFile *omfile=nullptr; //!< TFile pointer for the output memfile + + //Caches to permit FillN() calls + std::unordered_map> onedimcache; + std::unordered_map, std::vector>> twodimcache; + inline void FillN_All_Histograms(); +public: + HistPlotter(std::string outfile, std::string type); + inline void FlushToDisk(); //!< Writes all objects to file before closing, nesting objects in folders as is found necessary + inline void PrintObjects(); //!< Dump objects to std::cout for inspection + inline void ReadCuts(std::string); + inline TCutG* FindCut(std::string cut) { + return static_cast(cutsMap.at(cut)); + } + inline void set_barrier_limit(long long limit) { barrier_limit = limit; } + inline void barrier_increment() { + barrier_count++; + if(barrier_count == barrier_limit) { + FillN_All_Histograms(); + barrier_count=0; + } + } + /*! \fn void FindCut() + \brief + - Searches for a cut by name 'cut' in the internal list of cuts 'cutsMap'. Ugly fails (via unresolved at()) if such a cut isn't found. + \param filename - name of the plainxtext file containing the cut file locations and identifiers + \return Pointer to the TCutG object that matches the name. Very useful to use this as plotter.FindCut("protonbarrelpid")->IsInside(deltaE, E) for instance. + */ + + inline void SetNewTitle(std::string name, std::string title) { + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) return; //no warnings, could be changed in future + else + static_cast(oMap.at(name))->SetTitle(title.c_str()); // set new title + } + + //Smart functions that create a new histogram if it doesn't exist. + inline void FillGraph(const std::string &name, float valuex, float valuey, float errx=0, float erry=0); + inline void Fill1D(const std::string& name,int nbinsx, float xlow, float xhigh, float value); + inline void Fill2D(const std::string& name,int nbinsx, float xlow, float xhigh + ,int nbinsy, float ylow, float yhigh, float valuex, float valuey); + inline void Fill1D(const std::string& name,int nbinsx, float xlow, float xhigh, float value, const std::string& folder); + inline void Fill2D(const std::string& name,int nbinsx, float xlow, float xhigh + ,int nbinsy, float ylow, float yhigh, float valuex, float valuey, const std::string& folder); + //TObject* findObject(std::string key); +}; + +HistPlotter::HistPlotter(std::string outfile, std::string type="") { + /*! + \brief Constructor. Opens a TFile instance with the specified filename + \param outfile : std::string that holds the desired output ROOT filename + \return None + */ + if(type=="" || type == "TFILE") { + ofile = new TFile(outfile.c_str(),"recreate"); + filetype = TFILE; + } else if(type =="TMEMFILE") { + omfile = new TMemFile(outfile.c_str(),"recreate"); + filetype=TMEMFILE; + } else { + std::cout << "Unknown type "<< type << " specified for HistPlotter (use \"TFILE\" or \"TMEMFILE\"), using default \"TFILE\" " << std::endl; + ofile = new TFile(outfile.c_str(),"recreate"); + filetype = TFILE; + } + barrier_count=0; + barrier_limit=1000; +} + +void HistPlotter::FillN_All_Histograms() { + for(auto it=oMap.begin(); it!=oMap.end(); it++ ) { + //it->first is std::string 'name', it->second is the TObject + if(it->second->InheritsFrom("TH1F")) { + //FillN(size, array-of-doubles, array-of-weights); //we set array-of-weights to (1,1,1,.. (size) + static_cast(it->second)->FillN(onedimcache[it->first].size(), //size + onedimcache[it->first].data(), //array + std::vector(onedimcache[it->first].size(),1.0).data()); //weight of ones + onedimcache[it->first].clear(); + } else if(it->second->InheritsFrom("TH2F")) { + //FillN(size, array-of-doubles, array-of-weights); //we set array-of-weights to (1,1,1,.. (size)) + static_cast(it->second)->FillN(twodimcache[it->first].first.size(), //size + twodimcache[it->first].first.data(), //x array + twodimcache[it->first].second.data(), //y array + std::vector(twodimcache[it->first].first.size(),1.0).data()); //weight of ones + twodimcache[it->first].first.clear(); + twodimcache[it->first].second.clear(); + } + } + std::cout << "." << std::endl; +} +void HistPlotter::FlushToDisk() { + /*! \fn void FlushToDisk() + \brief Function that can be used at any point to exit smoothly by saving all ROOT objects in memory + to the output file before closing it. Obeys the binding of histograms to separate folders, if so specified. + \return No return -- void + */ + if(filetype==TMEMFILE && omfile) { + std::cout << "Not flushing a TMemfile .. exiting .." << std::endl; + delete omfile; + return; + } + if(ofile->IsZombie() || !ofile) { + std::cerr << "Output file is zombie, finishing up without writing to disk!" << std::endl; + return; + } + FillN_All_Histograms(); + for(auto it=oMap.begin(); it!=oMap.end(); it++ ) { + //omap maps: name(first) to object address(second). + // foldersForObjects maps: object address(first) to foldername(second) + auto result = foldersForObjects.find(it->second); //returns pair if found + if(result!=foldersForObjects.end()) { //we try to create folder if needed and cd to it + ofile->mkdir(result->second.c_str(),"",kTRUE); // args: name, title, returnExistingDirectory + ofile->cd(result->second.c_str()); + } else { + ofile->cd(); //toplevel for all default histograms. Default setting + } + it->second->Write(); + } + + //Create a directory for all cuts, and save all cuts in them + ofile->mkdir("gCUTS","",kTRUE); + ofile->cd("gCUTS"); + for(auto it=cutsMap.begin(); it!=cutsMap.end(); it++) { + (static_cast(it->second))->SetName(it->first.c_str()); + it->second->Write(); + } + ofile->Close(); + std::cout << "Wrote " << oMap.size() << " histograms to TFile " << std::string(ofile->GetName()) << std::endl; +} + +void HistPlotter::FillGraph(const std::string& name, float valuex, float valuey, float errx, float erry) { + /*! \fn void FillGraph() + \brief + - Creates a TGraphError in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TGraph* + + \param name name of the TGraph + \param valuex The xvalue + \param valuey The yvalue + \param errx The x error + \param erry The y error + \return No return void + */ + auto result = oMap.find(name); + if(result==oMap.end()) { + TGraphErrors *tempG = new TGraphErrors(); + tempG->SetName(name.c_str()); + oMap.insert(std::make_pair(name,static_cast(tempG))); + } + if(!oMap.at(name)->InheritsFrom("TGraphErrors")) { + std::cerr << "Object " << name << " refers to something other than a TGraph*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + // static_cast(oMap.at(name))->AddPointError(valuex,valuey,errx,erry); +} + +void HistPlotter::Fill1D(const std::string& name, int nbinsx, float xlow, float xhigh, float value) { + /*! \fn void Fill1D() + \brief + - Creates a TH1F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH1* + + \param name name of the TH1F histogram + \param nbinsx Number of bins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param value The bin corresponding to value in (nbinsx, xlow, xhigh) is incremented by 1 + \return No return void + */ + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH1F* temp1D = new TH1F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh); + oMap.insert(std::make_pair(name,static_cast(temp1D))); + onedimcache.insert(std::make_pair(name, std::vector())); + onedimcache[name].reserve(16384); + } else if(foldersForObjects.find(oMap.at(name))!=foldersForObjects.end()) { //shouldn't have a folder associated with it + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in toplevel .." << std::endl; + } + + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH1F")) { + std::cerr << "Object " << name << " refers to something other than a TH1*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + onedimcache[name].emplace_back(value); + //static_cast(oMap.at(name))->Fill(value); +} + +void HistPlotter::Fill1D(const std::string& name, int nbinsx, float xlow, float xhigh, float value, const std::string& foldername) { + /*! \fn void Fill1D() + \brief + - Creates a TH1F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH1* + - Remembers the foldername this particular histogram maps to, if provided. If not, defaults to toplevel. + + \param name name of the TH1F histogram + \param nbinsx Number of bins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param value The bin corresponding to value in (nbinsx, xlow, xhigh) is incremented by 1 + \param foldername Name of the folder to put this histogram into. Defaults to toplevel if left empty + \return No return -- void + */ + + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH1F* temp1D = new TH1F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh); + oMap.insert(std::make_pair(name,static_cast(temp1D))); + onedimcache.insert(std::make_pair(name, std::vector())); + onedimcache[name].reserve(16384); + if(foldername!="") { + if(folderList.find(foldername)==folderList.end()) { + folderList.insert(foldername); + } + foldersForObjects.insert(std::make_pair(static_cast(temp1D),foldername)); + } + } else { + //object is present in map, but we enforce unique names + //it must already have a folder attached to it + if(foldersForObjects.find(oMap.at(name))==foldersForObjects.end()) { + std::cerr << "Object " << name << " already registered at toplevel, choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } else if(foldersForObjects[oMap[name]]!=foldername) { + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } + } + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH1F")) { + std::cerr << "Object " << name << " refers to something other than a TH1*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + onedimcache[name].emplace_back(value); + //static_cast(oMap.at(name))->Fill(value); +} + +void HistPlotter::Fill2D(const std::string& name, int nbinsx, float xlow, float xhigh, int nbinsy, float ylow, float yhigh, float valuex, float valuey) { + /*! \fn void Fill2D() + \brief + - Creates a TH2F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH2* + \param name name of the TH1F histogram + \param nbinsx Number of xbins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param nbinsy Number of ybins in the histogram + \param ylow Lower limit on y-axis + \param yhigh Upper limit on y-axis + \param valuex + \param valuey The bin corresponding to (valuex, valuey) in (nbinsx, xlow, xhigh, ybinsx, ylow, yhigh) is incremented by 1 + \return No return -- void + */ + + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH2F* temp2D = new TH2F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh, nbinsy, ylow, yhigh); + oMap.insert(std::make_pair(name,static_cast(temp2D))); + twodimcache.insert(std::make_pair(name, std::make_pair(std::vector(),std::vector()))); + twodimcache[name].first.reserve(16384); + twodimcache[name].second.reserve(16384); + } else if(foldersForObjects.find(oMap.at(name))!=foldersForObjects.end()) { //shouldn't have a folder associated with it + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in toplevel .." << std::endl; + } + + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH2F")) { + std::cerr << "Object " << name << " refers to something other than a TH2*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + twodimcache[name].first.emplace_back(valuex); + twodimcache[name].second.emplace_back(valuey); + //static_cast(oMap.at(name))->Fill(valuex,valuey); +} + +void HistPlotter::Fill2D(const std::string& name, int nbinsx, float xlow, float xhigh, int nbinsy, float ylow, float yhigh, float valuex, float valuey, const std::string& foldername) { + /*! \fn void Fill2D() + \brief + - Creates a TH2F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH2* + - Remembers the foldername this particular histogram maps to, if provided. If not defaults to toplevel + + \param name name of the TH1F histogram + \param nbinsx Number of xbins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param nbinsy Number of ybins in the histogram + \param ylow Lower limit on y-axis + \param yhigh Upper limit on y-axis + \param valuex + \param valuey The bin corresponding to (valuex, valuey) in (nbinsx, xlow, xhigh, ybinsx, ylow, yhigh) is incremented by 1 + \param foldername Name of the folder to put this histogram into. Defaults to toplevel if left empty + \return No return -- void + */ + + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH2F* temp2D = new TH2F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh, nbinsy, ylow, yhigh); + oMap.insert(std::make_pair(name,static_cast(temp2D))); + twodimcache.insert(std::make_pair(name, std::make_pair(std::vector(),std::vector()))); + twodimcache[name].first.reserve(16384); + twodimcache[name].second.reserve(16384); + if(foldername!="") { + if(folderList.find(foldername)==folderList.end()) { + folderList.insert(foldername); + } + foldersForObjects.insert(std::make_pair(static_cast(temp2D),foldername)); + } + } else { + //object is present in map, but we enforce unique names + //it must already have a folder attached to it + if(foldersForObjects.find(oMap.at(name))==foldersForObjects.end()) { + std::cerr << "Object " << name << " already registered at toplevel, choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } else if(foldersForObjects[oMap.at(name)]!=foldername) { + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } + } + + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH2F")) { + std::cerr << "Object " << name << " refers to something other than a TH2*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + twodimcache[name].first.emplace_back(valuex); + twodimcache[name].second.emplace_back(valuey); + //static_cast(oMap.at(name))->Fill(valuex,valuey); +} + +void HistPlotter::ReadCuts(std::string filename) { + /*! \fn void ReadCuts() + \brief Reads a list of cuts from a file. The file must have the format below, two columns + - Column#1 - path to a file that contains a single TCutG object named "CUTG", the default name in ROOT. + - Column#2 - The identifier name you plan to use in the code, like 'protonbarrelpid' or something, that will be searched by FindCut() + \param filename name of the plainxtext file containing the cut file locations and identifiers + \return No return -- void + */ + + std::ifstream infile; + infile.open(filename); + std::string cutfilename, cutname; + for(std::string line; std::getline(infile, line); ) { + if(line.size()!=0 && line[0]=='#') + ; //don't do anything with '#' lines + else { + std::stringstream ss(line); + ss>>cutfilename>>cutname; + + TFile f(cutfilename.c_str()); + if(f.IsZombie()) { + std::cerr << "Cannot open cutfile " << cutfilename << " .. skipping.." << std::endl; + continue; + } + TCutG *cut = (TCutG*)(f.Get("CUTG")); + cutsMap.insert(std::make_pair(cutname,static_cast(cut))); + f.Close(); + } //else + }//for loop + infile.close(); +} + +void HistPlotter::PrintObjects() { + /* + void PrintObjects() + Prints the contents of the unordered_maps oMap and cutsMap to facilitate debugging + + */ + std::cout << "Type | Name " << std::endl; + std::cout << "---- | --------------------- " << std::endl; + for(auto it=oMap.begin(); it!=oMap.end(); it++ ) { + std::cout << it->second->ClassName() << " | "<< it->first << std::endl; + } + for(auto it=cutsMap.begin(); it!=cutsMap.end(); it++ ) { + std::cout << it->second->ClassName() << " | "<< it->first << std::endl; + } + std::cout << "---- | --------------------- " << std::endl; +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/Armory/Isotope.h b/anasen_analysis_vignesh/Armory/Armory/Isotope.h new file mode 100644 index 0000000..d44cdc9 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/Isotope.h @@ -0,0 +1,522 @@ +/*********************************************************************** + * + * This is Isotope.h, To extract the isotope mass from massXX.txt + * + *------------------------------------------------------- + * created by Ryan (Tsz Leung) Tang, Nov-18, 2018 + * email: goluckyryan@gmail.com + * ********************************************************************/ + + +#ifndef ISOTOPE_H +#define ISOTOPE_H + +#include +#include +#include +#include +#include +#include +#include "constant.h" // amu +#include //atoi +#include +using namespace std; + +string massData="mass20.txt"; + +// about the mass**.txt +// Mass Excess = (ATOMIC MASS - A)*amu | e.g. n : (1.088664.91585E-6-1)*amu +// mass excess uncertaintly +// BEA = (Z*M(1H) + N*M(1n) - Me(A,Z))/A , Me is the mass with electrons +// BEA = (Z*mp + N*mn - M(A,Z))/A , M is the mass without electrons + +class Isotope { +public: + int A, Z; + double Mass, MassError, BEA; + string Name, Symbol; + string dataSource; + + Isotope(){ dataSource = massData; }; + Isotope(int a, int z){ dataSource = massData; SetIso(a,z); }; + Isotope(string name){ dataSource = massData; SetIsoByName(name); }; + + void SetIso(int a, int z); + void SetIsoByName(string name); + + double CalSp(int Np, int Nn); // this for the Np-proton, Nn-neutron removal + double CalSp2(int a, int z); // this is for (a,z) nucleus removal + + double CalBeta(double T){ + // double Etot = Mass + T; + double gamma = 1 + T/Mass; + double beta = sqrt(1 - 1 / gamma / gamma ) ; + return beta; + } + + void Print(); + void ListShell(); + +private: + void FindMassByAZ(int a, int z); // give mass, massError, BEA, Name, Symbol; + void FindMassByName(string name); // give Z, mass, massError, BEA; + + int TwoJ(int nShell); + string Orbital(int nShell); + int magic(int i){ + switch (i){ + case 0: return 2; break; + case 1: return 8; break; + case 2: return 20; break; + case 3: return 28; break; + case 4: return 40; break; + case 5: return 50; break; + case 6: return 82; break; + case 7: return 128; break; + } + return 0; + } + + int magicShellID(int i){ + switch (i){ + case 0: return 0; break; + case 1: return 2; break; + case 2: return 5; break; + case 3: return 6; break; + case 4: return 9; break; + case 5: return 10; break; + case 6: return 15; break; + case 7: return 21; break; + } + return 0; + } + + int fileStartLine; + int fileEndLine; + int lineMass050_099; + int lineMass100_149; + int lineMass150_199; + int lineMass200; + + + void setFileLines(){ + fileStartLine = 37; + fileEndLine = 3594; + + lineMass050_099 = 466; + lineMass100_149 = 1160; + lineMass150_199 = 1994; + lineMass200 = 2774; + } + + char * heliosPath; + bool isFindOnce; + + +}; + +inline void Isotope::SetIso(int a, int z){ + this->A = a; + this->Z = z; + FindMassByAZ(a,z); +} + +inline void Isotope::SetIsoByName(string name){ + FindMassByName(name); +} + +inline void Isotope::FindMassByAZ(int A, int Z){ + string line; + int lineNum=0; + int list_A, list_Z; + + ifstream myfile; + int flag=0; + + setFileLines(); + + int numLineStart = fileStartLine; + int numLineEnd = fileEndLine; + + if ( A >= 50 && A < 100) numLineStart = lineMass050_099; + if ( A >=100 && A < 150) numLineStart = lineMass100_149; + if ( A >=150 && A < 200) numLineStart = lineMass150_199; + if ( A >=200 ) numLineStart = lineMass200; + + myfile.open(dataSource.c_str()); + + if (myfile.is_open()) { + while (/*! myfile.eof() &&*/ flag == 0 && lineNum = numLineStart ){ + list_Z = atoi((line.substr(10,5)).c_str()); + list_A = atoi((line.substr(15,5)).c_str()); + + if ( A == list_A && Z == list_Z) { + this->BEA = atof((line.substr(54,11)).c_str()); + this->Mass = list_Z*mp + (list_A-list_Z)*mn - this->BEA/1000*list_A; + this->MassError = atof((line.substr(65,7)).c_str()); + string str = line.substr(20,2); + str.erase(remove(str.begin(), str.end(), ' '), str.end()); + this->Symbol = str; + + ostringstream ss; + ss << A << this->Symbol; + this->Name = ss.str(); + flag = 1; + }else if ( list_A > A) { + this->BEA = -404; + this->Mass = -404; + this->MassError = -404; + this->Symbol = "non"; + this->Name = "non"; + break; + } + + } + } + + if( this->Name == "1H" ) this->Name = "p"; + if( this->Name == "2H" ) this->Name = "d"; + if( this->Name == "3H" ) this->Name = "t"; + if( this->Name == "4He" ) this->Name = "a"; + + myfile.close(); + }else { + printf("Unable to open %s\n", dataSource.c_str()); + } +} + +inline void Isotope::FindMassByName(string name){ + + // done seperate the Mass number and the name + if( name == "n" ) { + this->Name = "1n"; + this->BEA = 0; + this->Mass = mn; + this->MassError = 0; + this->Name = "n"; + this->A = 1; + this->Z = 0; + return; + } + if( name == "p" ) name = "1H"; + if( name == "d" ) name = "2H"; + if( name == "t" ) name = "3H"; + if( name == "a" ) name = "4He"; + + string temp = name; + int lastDigit = 0; + + for(int i=0; temp[i]; i++){ + if(temp[i] == '0') lastDigit = i; + if(temp[i] == '1') lastDigit = i; + if(temp[i] == '2') lastDigit = i; + if(temp[i] == '3') lastDigit = i; + if(temp[i] == '4') lastDigit = i; + if(temp[i] == '5') lastDigit = i; + if(temp[i] == '6') lastDigit = i; + if(temp[i] == '7') lastDigit = i; + if(temp[i] == '8') lastDigit = i; + if(temp[i] == '9') lastDigit = i; + } + + this->Symbol = temp.erase(0, lastDigit +1); + //check is Symbol is 2 charaters, if not, add " " at the end + if( this->Symbol.length() == 1 ){ + this->Symbol = this->Symbol + " "; + } + + + temp = name; + int len = temp.length(); + temp = temp.erase(lastDigit+1, len); + + this->A = atoi(temp.c_str()); + //printf(" Symbol = |%s| , Mass = %d\n", this->Symbol.c_str(), this->A); + + // find the nucleus in the data + string line; + int lineNum=0; + int list_A; + string list_symbol; + + ifstream myfile; + int flag=0; + + setFileLines(); + + int numLineStart = fileStartLine; + int numLineEnd = fileEndLine; + + if ( A >= 50 && A < 100) numLineStart = lineMass050_099; + if ( A >=100 && A < 150) numLineStart = lineMass100_149; + if ( A >=150 && A < 200) numLineStart = lineMass150_199; + if ( A >=200 ) numLineStart = lineMass200; + + myfile.open(dataSource.c_str()); + + if (myfile.is_open()) { + while (/*! myfile.eof() &&*/ flag == 0 && lineNum = numLineStart ){ + list_symbol = line.substr(20,2); + list_A = atoi((line.substr(15,5)).c_str()); + + //printf(" A = %d, Sym = |%s| \n", list_A, list_symbol.c_str()); + + if ( this->A == list_A && this->Symbol == list_symbol) { + this->Z = atoi((line.substr(10,5)).c_str()); + this->BEA = atof((line.substr(54,11)).c_str()); + this->Mass = this->Z*mp + (list_A-this->Z)*mn - this->BEA/1000*list_A; + this->MassError = atof((line.substr(65,7)).c_str()); + + string str = line.substr(20,2); + str.erase(remove(str.begin(), str.end(), ' '), str.end()); + this->Symbol = str; + + ostringstream ss; + ss << this->A << this->Symbol; + this->Name = ss.str(); + flag = 1; + }else if ( list_A > this->A) { + this->BEA = -404; + this->Mass = -404; + this->MassError = -404; + this->Symbol = "non"; + this->Name = "non"; + break; + } + + } + } + myfile.close(); + }else { + printf("Unable to open %s\n", dataSource.c_str()); + } +} + +inline double Isotope::CalSp(int Np, int Nn){ + Isotope nucleusD(A - Np - Nn, Z - Np); + + if( nucleusD.Mass != -404){ + return nucleusD.Mass + Nn*mn + Np*mp - this->Mass; + }else{ + return -404; + } +} + +inline double Isotope::CalSp2(int a, int z){ + Isotope nucleusD(A - a , Z - z); + Isotope nucleusS(a,z); + + if( nucleusD.Mass != -404 && nucleusS.Mass != -404){ + return nucleusD.Mass + nucleusS.Mass - this->Mass; + }else{ + return -404; + } +} + +inline int Isotope::TwoJ(int nShell){ + + switch(nShell){ + case 0: return 1; break; // 0s1/2 + case 1: return 3; break; // 0p3/2 + case 2: return 1; break; // 0p1/2 -- 8 + case 3: return 5; break; // 0d5/2 + case 4: return 1; break; // 1s1/2 + case 5: return 3; break; // 0d3/2 -- 20 + case 6: return 7; break; // 0f7/2 -- 28 + case 7: return 3; break; // 1p3/2 + case 8: return 1; break; // 1p1/2 + case 9: return 5; break; // 0f5/2 -- 40 + case 10: return 9; break; // 0g9/2 -- 50 + case 11: return 7; break; // 0g7/2 + case 12: return 5; break; // 1d5/2 + case 13: return 11; break; // 0h11/2 + case 14: return 3; break; // 1d3/2 + case 15: return 1; break; // 2s1/2 -- 82 + case 16: return 9; break; // 0h9/2 + case 17: return 7; break; // 1f7/2 + case 18: return 13; break; // 0i13/2 + case 19: return 3; break; // 2p3/2 + case 20: return 5; break; // 1f5/2 + case 21: return 1; break; // 1p1/2 -- 126 + case 22: return 9; break; // 1g9/2 + case 23: return 11; break; // 0i11/2 + case 24: return 15; break; // 0j15/2 + case 25: return 5; break; // 2d5/2 + case 26: return 1; break; // 3s1/2 + case 27: return 3; break; // 2d3/2 + case 28: return 7; break; // 1g7/2 + } + + return 0; +} + +inline string Isotope::Orbital(int nShell){ + + switch(nShell){ + case 0: return "0s1 "; break; // + case 1: return "0p3 "; break; // + case 2: return "0p1 "; break; //-- 8 + case 3: return "0d5 "; break; // + case 4: return "1s1 "; break; // + case 5: return "0d3 "; break; //-- 20 + case 6: return "0f7 "; break; //-- 28 + case 7: return "1p3 "; break; // + case 8: return "1p1 "; break; // + case 9: return "0f5 "; break; //-- 40 + case 10: return "0g9 "; break; //-- 50 + case 11: return "0g7 "; break; // + case 12: return "1d5 "; break; // + case 13: return "0h11"; break; // + case 14: return "1d3 "; break; // + case 15: return "2s1 "; break; //-- 82 + case 16: return "0h9 "; break; // + case 17: return "1f7 "; break; // + case 18: return "0i13"; break; // + case 19: return "2p3 "; break; // + case 20: return "1f5 "; break; // + case 21: return "1p1 "; break; //-- 126 + case 22: return "1g9 "; break; // + case 23: return "0i11"; break; // + case 24: return "0j15"; break; // + case 25: return "2d5 "; break; // + case 26: return "3s1 "; break; // + case 27: return "2d3 "; break; // + case 28: return "1g7 "; break; // + } + + return "nan"; +} + +inline void Isotope::ListShell(){ + + if( Mass < 0 ) return; + + int n = A-Z; + int p = Z; + + int k = std::min(n,p); + int nMagic = 0; + for( int i = 0; i < 7; i++){ + if( magic(i) < k && k <= magic(i+1) ){ + nMagic = i; + break; + } + } + + int coreShell = magicShellID(nMagic-1); + int coreZ1 = magic(nMagic-1); + int coreZ2 = magic(nMagic); + + Isotope core1( 2*coreZ1, coreZ1); + Isotope core2( 2*coreZ2, coreZ2); + + printf("------------------ Core:%3s, inner Core:%3s \n", (core2.Name).c_str(), (core1.Name).c_str()); + printf(" || "); + int t = std::max(n,p); + int nShell = 0; + do{ + int occ = TwoJ(nShell)+1; + if( nShell > coreShell) { + printf("%4s", Orbital(nShell).c_str()); + if( nShell == 0 || nShell == 2 || nShell == 5 || nShell ==6 || nShell == 9 || nShell == 10 || nShell == 15 || nShell == 21){ + printf("|"); + }else{ + printf(","); + } + } + t = t - occ; + nShell++; + }while( t > 0 && nShell < 29); + for( int i = 1; i <= 6; i++){ + if (nShell < 28) { + printf("%4s,", Orbital(nShell).c_str()); + }else if( nShell == 28 ) { + printf("%4s", Orbital(nShell).c_str()); + } + nShell ++; + } + if (nShell < 29) printf("%4s", Orbital(nShell).c_str()); + printf("\n"); + + + printf(" Z = %3d || ", p); + nShell = 0; + do{ + int occ = TwoJ(nShell)+1; + if( nShell > coreShell ){ + if( p > occ ) { + printf("%-4d", occ); + if( nShell == 0 || nShell == 2 || nShell == 5 || nShell ==6 || nShell == 9 || nShell == 10 || nShell == 15 || nShell == 21){ + printf("|"); + }else{ + printf(","); + } + }else{ + printf("%-4d", p); + } + } + p = p - occ; + nShell++; + }while( p > 0 && nShell < 29); + printf("\n"); + + printf(" N = %3d || ", n); + nShell = 0; + do{ + int occ = TwoJ(nShell)+1; + if ( nShell > coreShell ){ + if( n > occ ) { + printf("%-4d", occ); + if( nShell == 0 || nShell == 2 || nShell == 5 || nShell ==6 || nShell == 9 || nShell == 10 || nShell == 15 || nShell == 21){ + printf("|"); + }else{ + printf(","); + } + }else{ + printf("%-4d", n); + } + } + n = n - occ; + nShell++; + }while( n > 0 && nShell < 29); + printf("\n"); + + printf("------------------ \n"); +} + + +inline void Isotope::Print(){ + + if (Mass > 0){ + + dataSource = massData; + + printf(" using mass data : %s \n", dataSource.c_str()); + printf(" mass of \e[47m\e[31m%s\e[m nucleus (Z,A)=(%3d,%3d) is \e[47m\e[31m%12.5f\e[m MeV, BE/A=%7.5f MeV\n", Name.c_str(), Z, A, Mass, BEA/1000.); + printf(" total BE : %12.5f MeV\n",BEA*A/1000.); + printf(" mass in amu : %12.5f u\n",Mass/amu); + printf(" mass excess : %12.5f MeV\n", Mass + Z*0.510998950 - A*amu); + printf("-------------- Seperation energy \n"); + printf(" S1p: %8.4f| S1n: %8.4f| S(2H ): %8.4f| S1p1n : %8.4f\n", CalSp(1, 0), CalSp(0, 1), CalSp2(2, 1), CalSp(1, 1)); + printf(" S2p: %8.4f| S2n: %8.4f| S(3He): %8.4f| S(3H) : %8.4f\n", CalSp(2, 0), CalSp(0, 2), CalSp2(3, 2), CalSp2(3, 1)); + printf(" S3p: %8.4f| S3n: %8.4f| S(4He): %8.4f|\n", CalSp(3, 0), CalSp(0, 3), CalSp2(4, 2)); + printf(" S4p: %8.4f| S4n: %8.4f| \n", CalSp(4, 0), CalSp(0, 4)); + + }else{ + printf("Error %6.0f, no nucleus with (Z,A) = (%3d,%3d). \n", Mass, Z, A); + } + + +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/Armory/LICENSE b/anasen_analysis_vignesh/Armory/Armory/LICENSE new file mode 100644 index 0000000..f288702 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/LICENSE @@ -0,0 +1,674 @@ + GNU GENERAL PUBLIC LICENSE + Version 3, 29 June 2007 + + Copyright (C) 2007 Free Software Foundation, Inc. + Everyone is permitted to copy and distribute verbatim copies + of this license document, but changing it is not allowed. + + Preamble + + The GNU General Public License is a free, copyleft license for +software and other kinds of works. + + The licenses for most software and other practical works are designed +to take away your freedom to share and change the works. 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If your program is a subroutine library, you +may consider it more useful to permit linking proprietary applications with +the library. If this is what you want to do, use the GNU Lesser General +Public License instead of this License. But first, please read +. diff --git a/anasen_analysis_vignesh/Armory/Armory/Makefile b/anasen_analysis_vignesh/Armory/Armory/Makefile new file mode 100644 index 0000000..9cc4957 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/Makefile @@ -0,0 +1,32 @@ +######################################################################## +# +# +######################################################################### + +CC = g++ + +#COPTS = -fPIC -DLINUX -O2 -std=c++17 -lpthread +COPTS = -fPIC -DLINUX -g -O0 -Wall -std=c++17 -lpthread + +ROOTLIBS = `root-config --cflags --glibs` + +ALL = Mapper EventBuilder#AnasenMS + +######################################################################### + +all : $(ALL) + +clean : + /bin/rm -f $(OBJS) $(ALL) + +Mapper : Mapper.cpp ../mapping.h ClassDet.h + @echo "--------- making Mapper" + $(CC) $(COPTS) -o Mapper Mapper.cpp $(ROOTLIBS) + +# AnasenMS : constant.h Isotope.h ClassTransfer.h ClassSX3.h ClassPW.h ClassAnasen.h anasenMS.cpp +# @echo "--------- making ANASEN Monte Carlo" +# $(CC) $(COPTS) -o AnasenMS anasenMS.cpp $(ROOTLIBS) + +EventBuilder : EventBuilder.cpp ../ClassData.h fsuReader.h ../Hit.h + @echo "--------- making EventBuilder" + $(CC) $(COPTS) -o EventBuilder EventBuilder.cpp $(ROOTLIBS) diff --git a/anasen_analysis_vignesh/Armory/Armory/Mapper.cpp b/anasen_analysis_vignesh/Armory/Armory/Mapper.cpp new file mode 100644 index 0000000..8030de1 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/Mapper.cpp @@ -0,0 +1,182 @@ +#include +#include + +#include +#include +#include +#include +#include + +#include "../mapping.h" +#include "ClassDet.h" + +//=============================== +int main(int argc, char **argv){ + + printf("=========================================\n"); + printf("=== Mapper ===\n"); + printf("=========================================\n"); + if (argc != 2) { + printf("Incorrect number of arguments:\n"); + printf("%s [inFile]\n", argv[0]); + printf("\n\n"); + return 1; + } + + ///============= read input + std::string inFileName = argv[1]; + + PrintMapping(); + + TFile * inFile = new TFile(inFileName.c_str(), "READ"); + TTree * tree = (TTree*) inFile->Get("tree"); + unsigned long long totnumEntry = tree->GetEntries(); + + ULong64_t evID; + UInt_t multi; + UShort_t sn[MAXMULTI]; + UShort_t ch[MAXMULTI]; + UShort_t e[MAXMULTI]; + UShort_t e2[MAXMULTI]; + ULong64_t e_t[MAXMULTI]; + UShort_t e_f[MAXMULTI]; + + tree->SetBranchAddress("evID", &evID); + tree->SetBranchAddress("multi", &multi); + tree->SetBranchAddress("sn", sn); + tree->SetBranchAddress("ch", ch); + tree->SetBranchAddress("e", e); + tree->SetBranchAddress("e2", e2); + tree->SetBranchAddress("e_t", e_t); + tree->SetBranchAddress("e_f", e_f); + + ///================== new tree + TString outFileName = inFileName; + TString runStr = outFileName; + int pos = outFileName.Last('/'); + pos = outFileName.Index("_", pos+1); // find next "_" + runStr.Remove(0, pos+1); + runStr.Remove(3); + pos = outFileName.Index("_", pos+1); // find next "_" + outFileName.Remove(pos); // remove the rest + outFileName += "_mapped.root"; + + ULong_t eventID; + UInt_t run = runStr.Atoi(); + + Det sx3; + Det qqq; + Det pc ; + + printf(" Raw root file : %s\n", inFileName.c_str()); + printf(" Run : %03d\n", run); + printf(" total Entry : %lld \n", totnumEntry); + printf(" Out file name : %s \n", outFileName.Data()); + + TFile * saveFile = new TFile( outFileName,"RECREATE"); + TTree * newTree = new TTree("tree","tree"); + + + newTree->Branch("evID", &eventID,"eventID/l"); + newTree->Branch("run", &run,"run/i"); + + newTree->Branch("sx3Multi", &sx3.multi, "sx3Multi/s"); + newTree->Branch("sx3ID", &sx3.id, "sx3ID[sx3Multi]/s"); + newTree->Branch("sx3Ch", &sx3.ch, "sx3Ch[sx3Multi]/s"); + newTree->Branch("sx3E", &sx3.e, "sx3Energy[sx3Multi]/s"); + newTree->Branch("sx3T", &sx3.t, "sx3Time[sx3Multi]/l"); + + newTree->Branch("qqqMulti", &qqq.multi, "qqqMulti/s"); + newTree->Branch("qqqID", &qqq.id, "qqqID[qqqMulti]/s"); + newTree->Branch("qqqCh", &qqq.ch, "qqqCh[qqqMulti]/s"); + newTree->Branch("qqqE", &qqq.e, "qqqEnergy[qqqMulti]/s"); + newTree->Branch("qqqT", &qqq.t, "qqqTime[qqqMulti]/l"); + newTree->Branch("qqqSN", &qqq.sn, "qqqSN[qqqMulti]/s"); + + newTree->Branch("pcMulti", &pc.multi, "pcMulti/s"); + newTree->Branch("pcID", &pc.id, "pcID[pcMulti]/s"); + newTree->Branch("pcCh", &pc.ch, "pcCh[pcMulti]/s"); + newTree->Branch("pcE", &pc.e, "pcEnergy[pcMulti]/s"); + newTree->Branch("pcT", &pc.t, "pcTime[pcMulti]/l"); + + ///================== looping old tree and apply mapping + + //clock + // TBenchmark clock; + // Bool_t shown; + + for( unsigned long long ev = 0; ev < totnumEntry; ev++){ + tree->GetEntry(ev); + + eventID = evID; + sx3.multi = 0; + qqq.multi = 0; + pc.multi = 0; + + qqq.Clear(); + + for( unsigned int i = 0; i < multi; i++){ + + // printf("%10u/%10u| %5d, %2u, %6u, %14llu\n", i, multi, sn[i], ch[i], e[i], e_t[i] ); + + //globalCh = digi-ID * nCh(digi-iD) + ch + int globalCh = -1; + + for( int j = 0; j < nBd; j++){ + if( board.at(j) == sn[i]){ + globalCh = (sn[i] > 1000 ? j * 64 : 7*64 + (j-7) * 16) + ch[i]; //& = number V1740 + break; + } + } + + if( globalCh == -1) printf("ev %llu\n", ev); + + unsigned short ID = mapping[globalCh]; + + //=================================== sx3 + if( ID < 10000 ) { + sx3.id[sx3.multi] = ID / 100; + sx3.ch[sx3.multi] = ID % 100; + sx3.e[sx3.multi] = e[i]; + sx3.t[sx3.multi] = e_t[i]; + sx3.multi ++; + } + + //=================================== qqq + if( 10000 <= ID && ID < 20000 ) { + qqq.id[qqq.multi] = (ID - 10000) / 100; + qqq.ch[qqq.multi] = (ID - 10000) % 100; + qqq.e[qqq.multi] = e[i]; + qqq.t[qqq.multi] = e_t[i]; + qqq.sn[qqq.multi] = sn[i]; + qqq.multi ++; + } + + //=================================== pc + if( 20000 <= ID && ID < 30000 ) { + pc.id[pc.multi] = (ID - 20000) / 100; + pc.ch[pc.multi] = (ID - 20000) % 100; + pc.e[pc.multi] = e[i]; + pc.t[pc.multi] = e_t[i]; + pc.multi ++; + } + } + + saveFile->cd(); //set focus on this file + newTree->Fill(); + + if( eventID % 100 == 0 ) printf("%6lu/%6llu [%2d%%]\n\033[A\r", eventID, totnumEntry, TMath::Nint((eventID+1)*100./totnumEntry)); + + } + + inFile->Close(); + + saveFile->cd(); //set focus on this file + newTree->Write(); + UInt_t eventNumber = newTree->GetEntries(); + saveFile->Close(); + printf("-------------- done, %u\n", eventNumber); + + return 0; + +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/Armory/anasenMS.cpp b/anasen_analysis_vignesh/Armory/Armory/anasenMS.cpp new file mode 100644 index 0000000..162e64f --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/anasenMS.cpp @@ -0,0 +1,280 @@ +#include "TRandom.h" +#include "TFile.h" +#include "TTree.h" +#include "TH1.h" +#include "TH2.h" +#include "TStyle.h" +#include "TCanvas.h" +#include "TBenchmark.h" + +#include "ClassTransfer.h" +#include "ClassAnasen.h" + +//======== Gerneate light particle based on reaction +// find out the CalTrack and the real track +// find out the Q-value uncertaintly + +int main(int argc, char **argv){ + + printf("=========================================\n"); + printf("=== ANASEN Monte Carlo ===\n"); + printf("=========================================\n"); + + int numEvent = 1000000; + if( argc >= 2 ) numEvent = atoi(argv[1]); + + //Reaction + TransferReaction transfer; + + transfer.SetA(24,12, 0); + transfer.SetIncidentEnergyAngle(10, 0, 0); + transfer.Seta( 4, 2); + transfer.Setb( 1, 1); + + //TODO add alpha source + + std::vector ExAList = {0}; + std::vector ExList = {0, 1, 2}; + + double vertexXRange[2] = { -5, 5}; // mm + double vertexYRange[2] = { -5, 5}; + double vertexZRange[2] = { -100, 100}; + + double sigmaSX3_W = -1; // mm, < 0 use mid-point + double sigmaSX3_L = 3; // mm, < 0 use mid-point + double sigmaPW_A = 0; // from 0 to 1. + double sigmaPW_C = 0; // from 0 to 1. + + //################################################### + + printf("------------ Vertex :\n"); + printf("X : %7.2f - %7.2f mm\n", vertexXRange[0], vertexXRange[1]); + printf("Y : %7.2f - %7.2f mm\n", vertexYRange[0], vertexYRange[1]); + printf("Z : %7.2f - %7.2f mm\n", vertexZRange[0], vertexZRange[1]); + printf("------------ Uncertainty :\n"); + printf(" SX3 horizontal : %.1f\n", sigmaSX3_W); + printf(" SX3 vertical : %.1f\n", sigmaSX3_L); + printf(" Anode : %.1f mm\n", sigmaPW_A); + printf(" Cathode : %.1f mm\n", sigmaPW_C); + printf(" num_eve : %d \n",numEvent); + transfer.CalReactionConstant(); + + int nExA = ExAList.size(); + int nEx = ExList.size(); + + ANASEN * anasen = new ANASEN(); + SX3 * sx3 = anasen->GetSX3(); + PW * pw = anasen->GetPW(); + + TString saveFileName = "SimAnasen1.root"; + printf("\e[32m#################################### building Tree in %s\e[0m\n", saveFileName.Data()); + TFile * saveFile = new TFile(saveFileName, "recreate"); + TTree * tree = new TTree("tree", "tree"); + + double KEA; + tree->Branch("beamKEA", &KEA, "beamKEA/D"); + + double thetaCM, phiCM; + tree->Branch("thetaCM", &thetaCM, "thetaCM/D"); + tree->Branch("phiCM", &phiCM, "phiCM/D"); + + double thetab, phib, Tb; + double thetaB, phiB, TB; + tree->Branch("thetab", &thetab, "thetab/D"); + tree->Branch("phib", &phib, "phib/D"); + tree->Branch("Tb", &Tb, "Tb/D"); + tree->Branch("thetaB", &thetaB, "thetaB/D"); + tree->Branch("phiB", &phiB, "phiB/D"); + tree->Branch("TB", &TB, "TB/D"); + + int ExAID; + double ExA; + tree->Branch("ExAID", &ExAID, "ExAID/I"); + tree->Branch("ExA", &ExA, "ExA/D"); + + int ExID; + double Ex; + tree->Branch("ExID", &ExID, "ExID/I"); + tree->Branch("Ex", &Ex, "Ex/D"); + + double vertexX, vertexY, vertexZ; + tree->Branch("vX", &vertexX, "VertexX/D"); + tree->Branch("vY", &vertexY, "VertexY/D"); + tree->Branch("vZ", &vertexZ, "VertexZ/D"); + + double sx3X, sx3Y, sx3Z; + tree->Branch("sx3X", &sx3X, "sx3X/D"); + tree->Branch("sx3Y", &sx3Y, "sx3Y/D"); + tree->Branch("sx3Z", &sx3Z, "sx3Z/D"); + + int anodeID[2], cathodeID[2]; + tree->Branch("aID", anodeID, "anodeID/I"); + tree->Branch("cID", cathodeID, "cathodeID/I"); + + double anodeDist[2], cathodeDist[2]; + tree->Branch("aDist", anodeDist, "anodeDist/D"); + tree->Branch("cDist", cathodeDist, "cathodeDist/D"); + + int sx3ID, sx3Up, sx3Dn, sx3Bk; + double sx3ZFrac; + tree->Branch("sx3ID", &sx3ID, "sx3ID/I"); + tree->Branch("sx3Up", &sx3Up, "sx3Up/I"); + tree->Branch("sx3Dn", &sx3Dn, "sx3Dn/I"); + tree->Branch("sx3Bk", &sx3Bk, "sx3Bk/I"); + tree->Branch("sx3ZFrac", &sx3ZFrac, "sx3ZFrac/D"); + + double reTheta, rePhi; + tree->Branch("reTheta", &reTheta, "reconstucted_theta/D"); + tree->Branch("rePhi", &rePhi, "reconstucted_phi/D"); + + double reTheta1, rePhi1; + tree->Branch("reTheta1", &reTheta1, "reconstucted_theta1/D"); + tree->Branch("rePhi1", &rePhi1, "reconstucted_phi1/D"); + + double z0; + tree->Branch("z0", &z0, "reconstucted_Z/D"); + + + //========timer + TBenchmark clock; + bool shown ; + clock.Reset(); + clock.Start("timer"); + shown = false; + + //================================= Calculate event + for( int i = 0; i < numEvent ; i++){ + + ExAID = gRandom->Integer(nExA); + ExA = ExAList[ExAID]; + transfer.SetExA(ExA); + + ExID = gRandom->Integer(nEx); + Ex = ExList[ExID]; + transfer.SetExB(Ex); + + transfer.CalReactionConstant(); + + thetaCM = TMath::ACos(2 * gRandom->Rndm() - 1) ; + phiCM = (gRandom->Rndm() - 0.5) * TMath::TwoPi(); + + //==== Calculate reaction + TLorentzVector * output = transfer.Event(thetaCM, phiCM); + TLorentzVector Pb = output[2]; + TLorentzVector PB = output[3]; + + thetab = Pb.Theta() * TMath::RadToDeg(); + thetaB = PB.Theta() * TMath::RadToDeg(); + + Tb = Pb.E() - Pb.M(); + TB = PB.E() - PB.M(); + + phib = Pb.Phi() * TMath::RadToDeg(); + phiB = PB.Phi() * TMath::RadToDeg(); + + vertexX = (vertexXRange[1]- vertexXRange[0])*gRandom->Rndm() + vertexXRange[0]; + vertexY = (vertexYRange[1]- vertexYRange[0])*gRandom->Rndm() + vertexYRange[0]; + vertexZ = (vertexZRange[1]- vertexZRange[0])*gRandom->Rndm() + vertexZRange[0]; + + TVector3 vertex(vertexX, vertexY, vertexZ); + + TVector3 dir(1, 0, 0); + dir.SetTheta(thetab * TMath::DegToRad()); + dir.SetPhi(phib * TMath::DegToRad()); + + + pw->FindWireID(vertex, dir, false); + sx3->FindSX3Pos(vertex, dir, false); + + PWHitInfo hitInfo = pw->GetHitInfo(); + + anodeID[0] = hitInfo.nearestWire.first; + cathodeID[0] = hitInfo.nearestWire.second; + anodeID[1] = hitInfo.nextNearestWire.first; + cathodeID[1] = hitInfo.nextNearestWire.second; + + anodeDist[0] = hitInfo.nearestDist.first; + cathodeDist[0] = hitInfo.nearestDist.second; + anodeDist[1] = hitInfo.nextNearestDist.first; + cathodeDist[1] = hitInfo.nextNearestDist.second; + + sx3ID = sx3->GetID(); + if( sx3ID >= 0 ){ + sx3Up = sx3->GetChUp(); + sx3Dn = sx3->GetChDn(); + sx3Bk = sx3->GetChBk(); + sx3ZFrac = sx3->GetZFrac(); + + //Introduce uncertaity + // TVector3 hitPos = sx3->GetHitPos(); + TVector3 hitPos = sx3->GetHitPosWithSigma(sigmaSX3_W, sigmaSX3_L); + + sx3X = hitPos.X(); + sx3Y = hitPos.Y(); + sx3Z = hitPos.Z(); + + pw->CalTrack(hitPos, anodeID[0], cathodeID[0], false); + reTheta = pw->GetTrackTheta() * TMath::RadToDeg(); + rePhi = pw->GetTrackPhi() * TMath::RadToDeg(); + + pw->CalTrack2(hitPos, hitInfo, sigmaPW_A, sigmaPW_C, false); + reTheta1 = pw->GetTrackTheta() * TMath::RadToDeg(); + rePhi1 = pw->GetTrackPhi() * TMath::RadToDeg(); + + z0 = pw->GetZ0(); + + }else{ + sx3Up = -1; + sx3Dn = -1; + sx3Bk = -1; + sx3ZFrac = TMath::QuietNaN(); + + sx3X = TMath::QuietNaN(); + sx3Y = TMath::QuietNaN(); + sx3Z = TMath::QuietNaN(); + + // for( int i = 0; i < 12; i++){ + // sx3Index[i] = -1; + // } + + reTheta = TMath::QuietNaN(); + rePhi = TMath::QuietNaN(); + + reTheta1 = TMath::QuietNaN(); + rePhi1 = TMath::QuietNaN(); + + z0 = TMath::QuietNaN(); + + } + + tree->Fill(); + + //#################################################################### Timer + clock.Stop("timer"); + Double_t time = clock.GetRealTime("timer"); + clock.Start("timer"); + + if ( !shown ) { + if (fmod(time, 10) < 1 ){ + printf( "%10d[%2d%%]| %8.2f sec | expect: %5.1f min \n", i, TMath::Nint((i+1)*100./numEvent), time , numEvent*time/(i+1)/60); + shown = 1; + } + }else{ + if (fmod(time, 10) > 9 ){ + shown = 0; + } + } + + } + + tree->Write(); + int count = tree->GetEntries(); + saveFile->Close(); + + printf("=============== done. saved as %s. count(hit==1) : %d\n", saveFileName.Data(), count); + + delete anasen; + + return 0; + +} diff --git a/anasen_analysis_vignesh/Armory/Armory/constant.h b/anasen_analysis_vignesh/Armory/Armory/constant.h new file mode 100644 index 0000000..db83ec5 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Armory/constant.h @@ -0,0 +1,105 @@ +/*********************************************************************** + * + * This is constant.h, to provide various physical constants. + * + *------------------------------------------------------- + * created by Ryan (Tsz Leung) Tang, Nov-18, 2018 + * email: goluckyryan@gmail.com + * ********************************************************************/ + +#ifndef constant +#define constant +#include + +const double pi = acos(-1.0); +const double E = 2.718281828459 ; +const double hbar_SI = 1.054571628e-34; //Js +const double kB = 1.3806504e-23; //JK^-1 +const double e = 1.602176487e-19; //C +const double c_SI = 299792458; //ms^-1 +const double me_SI = 9.10938215e-31 ; //kg +const double mp_SI = 1.672621637e-27 ; //kg +const double mn_SI = 1.67492729e-27 ; //kg +const double NA = 6.022141e+23 ; //mol^-1 + +const double deg2rad = pi/180 ; +const double rad2deg = 180/pi ; + +//====================================================================== +const double amu = 931.49432; // MeV/c^2 +const double hbarc = 197.326979; // MeV fm; +const double c = 299.792458; // mm/ns; +const double ee = 1.439964454; // MeV.fm + +//====================================================================== +double kg2MeV(double m){ + return m*c_SI*c_SI/e/1e6; +} + +double T2Brho(double mass, int Z, int A, double T){ + //mass in MeV + // Z in e + // T in MeV/A + double gamma = (T*A + mass)/mass; + double beta = sqrt(1-1/gamma/gamma); + return mass*beta*gamma/Z/c; +} + +double Brho2T(double mass, int Z, int A, double Brho){ + //mass in MeV + // Z in e + return (sqrt(pow(Brho*Z*c,2)+mass*mass)-mass)/A; +} + +double T2beta(double mass, int A, double T){ + double gamma = 1.0 + T*A/mass; + return sqrt(1-1/gamma/gamma); +} + +double ev2nm(double eV){ + // photon energy to nm + return hbarc/2/pi/eV; +} + +//====================================================================== +const double mp = kg2MeV(mp_SI); +const double mn = kg2MeV(mn_SI); +const double hbar = 197.326979; + + +//====================================================================== +inline std::vector SplitStr(std::string tempLine, std::string splitter, int shift = 0){ + + std::vector output; + + size_t pos; + do{ + pos = tempLine.find(splitter); /// fine splitter + if( pos == 0 ){ ///check if it is splitter again + tempLine = tempLine.substr(pos+1); + continue; + } + + std::string secStr; + if( pos == std::string::npos ){ + secStr = tempLine; + }else{ + secStr = tempLine.substr(0, pos+shift); + tempLine = tempLine.substr(pos+shift); + } + + ///check if secStr is begin with space + while( secStr.substr(0, 1) == " ") secStr = secStr.substr(1); + + ///check if secStr is end with space + while( secStr.back() == ' ') secStr = secStr.substr(0, secStr.size()-1); + + output.push_back(secStr); + ///printf(" |%s---\n", secStr.c_str()); + + }while(pos != std::string::npos ); + + return output; +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/ClassAnasen.h b/anasen_analysis_vignesh/Armory/ClassAnasen.h new file mode 100644 index 0000000..90585b7 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassAnasen.h @@ -0,0 +1,314 @@ +#ifndef ClassAnasen_h +#define ClassAnasen_h + +#include +#include +#include + +#include "TGeoManager.h" +#include "TGeoVolume.h" +#include "TGeoBBox.h" +#include "TCanvas.h" +#include "TPolyMarker3D.h" +#include "TPolyLine3D.h" +#include "TRandom.h" + +#include "ClassSX3.h" +#include "ClassPW.h" + +class ANASEN{ +public: + ANASEN(); + ~ANASEN(); + + void SetUncertainties(double sx3W, double sx3L, double anode, double cathode){ + sigmaA = anode; + sigmaC = cathode; + sigmaW = sx3W; + sigmaL = sx3L; + } + + void DrawTrack(TVector3 pos, TVector3 direction, bool drawEstimatedTrack = false); + void DrawDeducedTrack(TVector3 sx3Pos, int anodeID, int cathodeID); + void DrawAnasen(int anodeID1 = -1, + int anodeID2 = -1, + int cathodeID1 = -1, + int cathodeID2 = -1, + int sx3ID = -1, + bool DrawQQQ = false ); + + + + PW * GetPW() {return pw;} + SX3 * GetSX3() {return sx3;} + +private: + + PW * pw; + SX3 * sx3; + + double sigmaA, sigmaC; // pw + double sigmaW, sigmaL; // sx3 + + const float qqqR1 = 50; + const float qqqR2 = 100; + const float qqqZPos = 23 + 75 + 30; + + void CalGeometry(); + + TGeoManager *geom; + TGeoVolume *worldBox; + + void Construct3DModel(int anodeID1 = -1, + int anodeID2 = -1, + int cathodeID1 = -1, + int cathodeID2 = -1, + int sx3ID = -1, + bool DrawQQQ = true); + +}; + +//!============================================== +inline ANASEN::ANASEN(){ + + pw = new PW(); + sx3 = new SX3(); + + CalGeometry(); + + geom = nullptr; + worldBox = nullptr; + +} + +inline ANASEN::~ANASEN(){ + + delete geom; + + delete pw; + delete sx3; + +} + +//!============================================== +inline void ANASEN::CalGeometry(){ + + sx3->ConstructGeo(); + pw->ConstructGeo(); + +} + +inline void ANASEN::Construct3DModel(int anodeID1, int anodeID2, int cathodeID1, int cathodeID2, int sx3ID, bool DrawQQQ ){ + + if( geom ) delete geom; + + // Create ROOT manager and master volume + geom = new TGeoManager("Detector", "ANASEN"); + + //--- define some materials + TGeoMaterial *matVacuum = new TGeoMaterial("Vacuum", 0,0,0); + TGeoMaterial *matAl = new TGeoMaterial("Al", 26.98,13,2.7); + //--- define some media + TGeoMedium *Vacuum = new TGeoMedium("Vacuum",1, matVacuum); + TGeoMedium *Al = new TGeoMedium("Root Material",2, matAl); + + //--- make the top container volume + Double_t worldx = 200.; //mm + Double_t worldy = 200.; //mm + Double_t worldz = 200.; //mm + worldBox = geom->MakeBox("ROOT", Vacuum, worldx, worldy, worldz); + geom->SetTopVolume(worldBox); + + //--- making axis + TGeoVolume *axisX = geom->MakeTube("axisX", Al, 0, 0.1, 5.); + axisX->SetLineColor(1); + worldBox->AddNode(axisX, 1, new TGeoCombiTrans(5, 0, 0., new TGeoRotation("rotA", 90., 90., 0.))); + TGeoVolume *axisY = geom->MakeTube("axisY", Al, 0, 0.1, 5.); + axisY->SetLineColor(1); + worldBox->AddNode(axisY, 1, new TGeoCombiTrans(0, 5, 0., new TGeoRotation("rotB", 0., 90., 0.))); + TGeoVolume *axisZ = geom->MakeTube("axisZ", Al, 0, 0.1, 5.); + axisZ->SetLineColor(1); + worldBox->AddNode(axisZ, 1, new TGeoTranslation(0, 0, 5)); + + //.......... convert to wire center dimensions + TGeoVolume *pcA = geom->MakeTube("tub1", Al, 0, 0.01, pw->GetAnodeLength()/2); + pcA->SetLineColor(4); + + int startID = 0; + int endID = pw->GetNumWire() - 1; + + if( anodeID1 >= 0 && anodeID2 >= 0 ){ + startID = anodeID1; + endID = anodeID2; + if( anodeID1 > anodeID2 ) { + endID = pw->GetNumWire() + anodeID2; + } + } + + for( int i = startID; i <= endID; i++){ + TVector3 a = pw->GetAnodneMid(i); + double wireTheta = pw->GetAnodeTheta(i) * TMath::RadToDeg(); + double wirePhi = pw->GetAnodePhi(i) * TMath::RadToDeg() + 90; + + worldBox->AddNode(pcA, i+1, new TGeoCombiTrans( a.X(), + a.Y(), + a.Z(), + new TGeoRotation("rot1", wirePhi, wireTheta, 0.))); + } + + TGeoVolume *pcC = geom->MakeTube("tub2", Al, 0, 0.01, pw->GetCathodeLength()/2); + pcC->SetLineColor(6); + + startID = 0; + endID = pw->GetNumWire() - 1; + + if( cathodeID1 >= 0 && cathodeID2 >= 0 ){ + startID = cathodeID1; + endID = cathodeID2; + if( cathodeID1 > cathodeID2 ) { + endID = pw->GetNumWire() + cathodeID2; + } + } + + for( int i = startID; i <= endID; i++){ + TVector3 a = pw->GetCathodneMid(i); + double wireTheta = pw->GetCathodeTheta(i) * TMath::RadToDeg(); + double wirePhi = pw->GetCathodePhi(i) * TMath::RadToDeg() + 90; + + worldBox->AddNode(pcC, i+1, new TGeoCombiTrans( a.X(), + a.Y(), + a.Z(), + new TGeoRotation("rot1", wirePhi , wireTheta, 0.))); + } + + TGeoVolume * sx3Det = geom->MakeBox("box", Al, 0.1, sx3->GetWidth()/2, sx3->GetLength()/2); + sx3Det->SetLineColor(kGreen+3); + + for( int i = 0; i < sx3->GetNumDet(); i++){ + if( sx3ID != -1 && i != sx3ID ) continue; + TVector3 aUp = sx3->GetUpMid(i); // center of the SX3 upstream + TVector3 aDn = sx3->GetDnMid(i); // center of the SX3 Downstream + double phi = sx3->GetDetPhi(i) * TMath::RadToDeg() + 90; + + worldBox->AddNode(sx3Det, 2*i+1., new TGeoCombiTrans( aUp.X(), + aUp.Y(), + aUp.Z(), + new TGeoRotation("rot1", phi, 0., 0.))); + worldBox->AddNode(sx3Det, 2*i+1., new TGeoCombiTrans( aDn.X(), + aDn.Y(), + aDn.Z(), + new TGeoRotation("rot1", phi, 0., 0.))); + } + + if( DrawQQQ ){ + TGeoVolume *qqq = geom->MakeTubs("qqq", Al, qqqR1, qqqR2, 0.5, 5, 85); + qqq->SetLineColor(7); + for( int i = 0; i < 4; i++){ + worldBox->AddNode(qqq, i+1, new TGeoCombiTrans( 0, + 0, + qqqZPos, + new TGeoRotation("rot1", 360/4 * (i), 0., 0.))); + } + } + +} + +//!============================================== Drawing functions +inline void ANASEN::DrawAnasen(int anodeID1, int anodeID2, int cathodeID1, int cathodeID2, int sx3ID, bool DrawQQQ ){ + + Construct3DModel(anodeID1, anodeID2, cathodeID1, cathodeID2, sx3ID, DrawQQQ); + + geom->CloseGeometry(); + geom->SetVisLevel(4); + worldBox->Draw("ogle"); + +} + +inline void ANASEN::DrawTrack(TVector3 pos, TVector3 direction, bool drawEstimatedTrack){ + + pw->FindWireID(pos, direction); + sx3->FindSX3Pos(pos, direction); + + std::pair wireID = pw->GetNearestID(); + + Construct3DModel(wireID.first, wireID.first, wireID.second, wireID.second, -1, false); + + double theta = direction.Theta() * TMath::RadToDeg(); + double phi = direction.Phi() * TMath::RadToDeg(); + // printf("Theta, Phi = %.2f %.2f \n", theta, phi); + // pos.Print(); + TGeoVolume * Track = geom->MakeTube("track", 0, 0, 0.1, 150.); + Track->SetLineColor(kRed); + worldBox->AddNode(Track, 1, new TGeoCombiTrans( pos.X(), pos.Y(), pos.Z(), new TGeoRotation("rotA", phi + 90, theta, 0.))); + + TGeoVolume * startPos = geom->MakeSphere("startPos", 0, 0, 3); + startPos->SetLineColor(kBlack); + worldBox->AddNode(startPos, 3, new TGeoCombiTrans( pos.X(), pos.Y(), pos.Z(), new TGeoRotation("rotA", 0, 0, 0.))); + + if( sx3->GetID() >= 0 ){ + //TVector3 hitPos = sx3->GetHitPos(); + TVector3 hitPos = sx3->GetHitPosWithSigma(sigmaW, sigmaL); + + TGeoVolume * hit = geom->MakeSphere("hitpos", 0, 0, 3); + hit->SetLineColor(kRed); + worldBox->AddNode(hit, 2, new TGeoCombiTrans( hitPos.X(), hitPos.Y(), hitPos.Z(), new TGeoRotation("rotA", 0, 0, 0.))); + + if( drawEstimatedTrack ){ + + {//===== simple + pw->CalTrack(hitPos, wireID.first, wireID.second, true); + + double thetaDeduce = pw->GetTrackTheta() * TMath::RadToDeg(); + double phiDeduce = pw->GetTrackPhi() * TMath::RadToDeg(); + + TGeoVolume * trackDeduce = geom->MakeTube("trackDeduce", 0, 0, 0.1, 100.); + trackDeduce->SetLineColor(kOrange); + worldBox->AddNode(trackDeduce, 1, new TGeoCombiTrans( hitPos.X(), hitPos.Y(), hitPos.Z(), new TGeoRotation("rotA", phiDeduce + 90, thetaDeduce, 0.))); + } + + {//===== complicated + PWHitInfo hitInfo = pw->GetHitInfo(); + pw->CalTrack2(hitPos, hitInfo, sigmaA, sigmaC, true); + + double thetaDeduce = pw->GetTrackTheta() * TMath::RadToDeg(); + double phiDeduce = pw->GetTrackPhi() * TMath::RadToDeg(); + + TGeoVolume * trackDeduce2 = geom->MakeTube("trackDeduce2", 0, 0, 0.1, 100.); + trackDeduce2->SetLineColor(kGreen); + worldBox->AddNode(trackDeduce2, 1, new TGeoCombiTrans( hitPos.X(), hitPos.Y(), hitPos.Z(), new TGeoRotation("rotA", phiDeduce + 90, thetaDeduce, 0.))); + } + } + + } + + geom->CloseGeometry(); + geom->SetVisLevel(4); + worldBox->Draw("ogle"); + +} + +inline void ANASEN::DrawDeducedTrack(TVector3 sx3Pos, int anodeID, int cathodeID){ + + pw->CalTrack(sx3Pos, anodeID, cathodeID); + + Construct3DModel(anodeID, anodeID, cathodeID, cathodeID, -1, false); + + double theta = pw->GetTrackTheta() * TMath::RadToDeg(); + double phi = pw->GetTrackPhi() * TMath::RadToDeg(); + + TGeoVolume * Track = geom->MakeTube("axisX", 0, 0, 0.1, 100.); + Track->SetLineColor(kRed); + worldBox->AddNode(Track, 1, new TGeoCombiTrans( sx3Pos.X(), sx3Pos.Y(), sx3Pos.Z(), new TGeoRotation("rotA", phi + 90, theta, 0.))); + + TGeoVolume * hit = geom->MakeSphere("hitpos", 0, 0, 3); + hit->SetLineColor(kRed); + worldBox->AddNode(hit, 2, new TGeoCombiTrans( sx3Pos.X(), sx3Pos.Y(), sx3Pos.Z(), new TGeoRotation("rotA", 0, 0, 0.))); + + geom->CloseGeometry(); + geom->SetVisLevel(4); + worldBox->Draw("ogle"); + +} + + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/ClassDet.h b/anasen_analysis_vignesh/Armory/ClassDet.h new file mode 100644 index 0000000..510cbb4 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassDet.h @@ -0,0 +1,64 @@ +#ifndef ClassDet_h +#define ClassDet_h + +#include + +#define MAXMULTI 1000 + +class Det{ +public: + Det(): multi(0) {Clear(); } + + unsigned short multi; // max 65535 + unsigned short id[MAXMULTI]; + unsigned short ch[MAXMULTI]; + unsigned short e[MAXMULTI]; + unsigned long long t[MAXMULTI]; + + unsigned short sn[MAXMULTI]; + unsigned short digiCh[MAXMULTI]; + + unsigned short index[MAXMULTI]; // id * nCh + ch; + bool used[MAXMULTI]; + + void Clear(){ + multi = 0; + for( int i = 0; i < MAXMULTI; i++){ + id[i] = 0; + ch[i] = 0; + e[i] = 0; + t[i] = 0; + index[i] = 0; + sn[i] = 0; + digiCh[i] = 0; + used[i] = false; + } + } + + void Print(){ + printf("=============================== multi : %u\n", multi); + for( int i = 0; i < multi; i++) { + printf(" %3d | %2d-%-2d(%5d) %5u %15llu \n", i, id[i], ch[i], index[i], e[i], t[i]); + } + } + + void SetDetDimension(unsigned short maxID, unsigned maxCh){ + nID = maxID; + nCh = maxCh; + } + + void CalIndex(){ + for( int i = 0; i < multi; i++){ + index[i] = id[i] * nCh + ch[i] ; + } + } + +private: + + unsigned short nID; + unsigned short nCh; + +}; + + +#endif diff --git a/anasen_analysis_vignesh/Armory/ClassPC1An.h b/anasen_analysis_vignesh/Armory/ClassPC1An.h new file mode 100644 index 0000000..8e06560 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassPC1An.h @@ -0,0 +1,246 @@ +#ifndef ClassPC_h +#define ClassPC_h + +#include +#include +#include +#include + +struct PCHit_1An{ + std::pair nearestWire; // anode, cathode + std::pair nearestDist; // anode, cathode + + short nextNearestWire; // cathode + double nextNearestDist; // cathode + + void Clear(){ + nearestWire.first = -1; + nearestWire.second = -1; + nearestDist.first = 999999999; + nearestDist.second = 999999999; + nextNearestWire= -1; + nextNearestDist = 999999999; + } +}; + +//!######################################################## +class PC{ // proportional wire +public: + PC(){ ClearHitInfo();}; + ~PC(){}; + + PCHit_1An GetHitInfo() const {return hitInfo;} + std::pair GetNearestID() const {return hitInfo.nearestWire;} + std::pair GetNearestDistance() const {return hitInfo.nearestDist;} + short Get2ndNearestID() const {return hitInfo.nextNearestWire;} + double Get2ndNearestDistance() const {return hitInfo.nextNearestDist;} + + TVector3 GetTrackPos() const {return trackPos;} + TVector3 GetTrackVec() const {return trackVec;} + double GetTrackTheta() const {return trackVec.Theta();} + double GetTrackPhi() const {return trackVec.Phi();} + double GetZ0(); + + int GetNumWire() const {return nWire;} + double GetDeltaAngle() const {return dAngle;} + double GetAnodeLength() const {return anodeLength;} + double GetCathodeLength() const {return cathodeLength;} + TVector3 GetAnodeDn(short id) const {return An[id].first;} + TVector3 GetAnodeUp(short id) const {return An[id].second;} + TVector3 GetCathodeDn(short id) const {return Ca[id].first;} + TVector3 GetCathodeUp(short id) const {return Ca[id].second;} + + TVector3 GetAnodneMid(short id) const {return (An[id].first + An[id].second) * 0.5; } + double GetAnodeTheta(short id) const {return (An[id].first - An[id].second).Theta();} + double GetAnodePhi(short id) const {return (An[id].first - An[id].second).Phi();} + + TVector3 GetCathodneMid(short id) const {return (Ca[id].first + Ca[id].second) * 0.5; } + double GetCathodeTheta(short id) const {return (Ca[id].first - Ca[id].second).Theta();} + double GetCathodePhi(short id) const {return (Ca[id].first - Ca[id].second).Phi();} + + void ClearHitInfo(); + void ConstructGeo(); + void FindWireID(TVector3 pos, TVector3 direction, bool verbose = false); + void CalTrack3(TVector3 sx3Pos, PCHit_1An hitInfo, double sigmaA = 0, double sigmaC = 0, bool verbose = false); + + void Print(){ + printf(" The nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nearestWire.first, + hitInfo.nearestDist.first, + hitInfo.nearestWire.second, + hitInfo.nearestDist.second); + + printf(" The 2nd nearest Cathode: %2d(%5.2f)\n", hitInfo.nextNearestWire, + hitInfo.nextNearestDist); + } + +private: + + // PCHitInfo hitInfo; + PCHit_1An hitInfo; + + TVector3 trackPos; + TVector3 trackVec; + + const int nWire = 24; + const int wireShift = 3; + const float zLen = 380; //mm + const float radiusA = 37; + const float radiusC = 43; + + double dAngle; + double anodeLength; + double cathodeLength; + + std::vector> An; // the anode wire position vector in space + std::vector> Ca; // the cathode wire position vector in space + + double Distance(TVector3 a1, TVector3 a2, TVector3 b1, TVector3 b2){ + TVector3 na = a1 - a2; + TVector3 nb = b1 - b2; + TVector3 nd = (na.Cross(nb)).Unit(); + return TMath::Abs(nd.Dot(a1-b2)); + } + +}; + +inline void PC::ClearHitInfo(){ + hitInfo.Clear(); +} + +inline void PC::ConstructGeo(){ + + An.clear(); + Ca.clear(); + + std::pair p1; // anode + std::pair q1; // cathode + + //anode and cathode start at pos-Y axis and count in right-Hand + //anode wire shift is right-hand. + //cathode wire shift is left-hand. + + for(int i = 0; i < nWire; i++ ){ + // Anode rotate right-hand + p1.first.SetXYZ( radiusA * TMath::Cos( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + radiusA * TMath::Sin( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + zLen/2); + p1.second.SetXYZ( radiusA * TMath::Cos( TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + radiusA * TMath::Sin( TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + -zLen/2); + An.push_back(p1); + + // Cathod rotate left-hand + q1.first.SetXYZ( radiusC * TMath::Cos( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + radiusC * TMath::Sin( TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + zLen/2); + q1.second.SetXYZ( radiusC * TMath::Cos( TMath::TwoPi() / nWire * (i - wireShift) + TMath::PiOver2()), + radiusC * TMath::Sin( TMath::TwoPi() / nWire * (i - wireShift) + TMath::PiOver2()), + -zLen/2); + Ca.push_back(q1); + } + + dAngle = wireShift * TMath::TwoPi() / nWire; + anodeLength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusA * TMath::Sin(dAngle/2),2) ); + cathodeLength = TMath::Sqrt( zLen*zLen + TMath::Power(2* radiusC * TMath::Sin(dAngle/2),2) ); +} + +inline void PC::FindWireID(TVector3 pos, TVector3 direction, bool verbose ){ + + hitInfo.Clear(); + double phi = direction.Phi(); + + for( int i = 0; i < nWire; i++){ + + double disA = 99999999; + double phiS = An[i].first.Phi() - TMath::PiOver4(); + double phiL = An[i].second.Phi() + TMath::PiOver4(); + // printf("A%2d: %f %f | %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg(), phi * TMath::RadToDeg()); + if( phi > 0 && phiS > phiL ) phiL = phiL + TMath::TwoPi(); + if( phi < 0 && phiS > phiL ) phiS = phiS - TMath::TwoPi(); + + if( phiS < phi && phi < phiL) { + disA = Distance( pos, pos + direction, An[i].first, An[i].second); + if( disA < hitInfo.nearestDist.first ){ + hitInfo.nearestDist.first = disA; + hitInfo.nearestWire.first = i; + } + } + + double disC = 99999999; + phiS = Ca[i].second.Phi()- TMath::PiOver4(); + phiL = Ca[i].first.Phi() + TMath::PiOver4(); + // printf("C%2d: %f %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg()); + if( phi > 0 && phiS > phiL ) phiL = phiL + TMath::TwoPi(); + if( phi < 0 && phiS > phiL ) phiS = phiS - TMath::TwoPi(); + + if(phiS < phi && phi < phiL) { + disC = Distance( pos, pos + direction, Ca[i].first, Ca[i].second); + if( disC < hitInfo.nearestDist.second ){ + hitInfo.nearestDist.second = disC; + hitInfo.nearestWire.second = i; + } + } + + if(verbose) printf(" %2d | %8.2f, %8.2f\n", i, disA, disC); + } + + short cathode1 = hitInfo.nearestWire.second; + short ccc1 = cathode1 - 1; if( ccc1 < 0 ) ccc1 += nWire; + short ccc2 = (cathode1 + 1) % nWire; + + double haha1 = Distance( pos, pos + direction, Ca[ccc1].first, Ca[ccc1].second); + double haha2 = Distance( pos, pos + direction, Ca[ccc2].first, Ca[ccc2].second); + if( haha1 < haha2){ + hitInfo.nextNearestWire = ccc1; + hitInfo.nextNearestDist = haha1; + }else{ + hitInfo.nextNearestWire = ccc2; + hitInfo.nextNearestDist= haha2; + } + + if( verbose ) Print(); +} + + +inline void PC::CalTrack3(TVector3 sx3Pos, PCHit_1An hitInfo, double sigmaA, double sigmaC, bool verbose){ + + trackPos = sx3Pos; + + double p1 = TMath::Abs(hitInfo.nearestDist.first + gRandom->Gaus(0, sigmaA)); + short anodeID1 = hitInfo.nearestWire.first; + + double q1 = TMath::Abs(hitInfo.nearestDist.second + gRandom->Gaus(0, sigmaC)); + double q2 = TMath::Abs(hitInfo.nextNearestDist+ gRandom->Gaus(0, sigmaC)); + double fracC = q1 / (q1 + q2); + short cathodeID1 = hitInfo.nearestWire.second; + short cathodeID2 = hitInfo.nextNearestWire; + TVector3 shiftC1 = (Ca[cathodeID2].first - Ca[cathodeID1].first) * fracC; + TVector3 shiftC2 = (Ca[cathodeID2].second - Ca[cathodeID1].second) * fracC; + + TVector3 a1 = An[anodeID1].first; + + TVector3 c1 = Ca[cathodeID1].first + shiftC1; + TVector3 c2 = Ca[cathodeID1].second + shiftC2; + + TVector3 n1 = (sx3Pos - a1).Unit(); + TVector3 n2 = (c1 - c2).Cross((sx3Pos - c2)).Unit(); + + // if the handiness of anode and cathode revered, it should be n2 cross n1 + trackVec = (n2.Cross(n1)).Unit(); + + if( verbose ) printf("Theta, Phi = %f, %f \n", trackVec.Theta() *TMath::RadToDeg(), trackVec.Phi()*TMath::RadToDeg()); + +} + +inline double PC::GetZ0(){ + + double x = trackPos.X(); + double y = trackPos.Y(); + double rho = TMath::Sqrt(x*x + y*y); + double theta = trackVec.Theta(); + + return trackPos.Z() - rho / TMath::Tan(theta); + +} + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/ClassPW.h b/anasen_analysis_vignesh/Armory/ClassPW.h new file mode 100644 index 0000000..9ccc817 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassPW.h @@ -0,0 +1,535 @@ +#ifndef ClassPW_h +#define ClassPW_h + +#include +#include +#include +#include +#include + +struct PWHitInfo +{ + std::pair nearestWire; // anode, cathode + std::pair nearestDist; // anode, cathode + + std::pair nextNearestWire; // anode, cathode + std::pair nextNearestDist; // anode, cathode + + void Clear() + { + nearestWire.first = -1; + nearestWire.second = -1; + nearestDist.first = 999999999; + nearestDist.second = 999999999; + nextNearestWire.first = -1; + nextNearestWire.second = -1; + nextNearestDist.first = 999999999; + nextNearestDist.second = 999999999; + } +}; + +struct Coord +{ + float x, y, z; + Coord() : x(0), y(0), z(0) {} + Coord(const TVector3 &vec) + { + x = vec.X(); // TVector3's X() returns the x-coordinate + y = vec.Y(); // TVector3's Y() returns the y-coordinate + z = vec.Z(); // TVector3's Z() returns the z-coordinate + } +}; + +//! ######################################################## +class PW +{ // proportional wire +public: + PW() { ClearHitInfo(); }; + ~PW() {}; + + PWHitInfo GetHitInfo() const { return hitInfo; } + std::pair GetNearestID() const { return hitInfo.nearestWire; } + std::pair GetNearestDistance() const { return hitInfo.nearestDist; } + std::pair Get2ndNearestID() const { return hitInfo.nextNearestWire; } + std::pair Get2ndNearestDistance() const { return hitInfo.nextNearestDist; } + + std::vector> An; // the anode wire position vector in space + std::vector> Ca; // the cathode wire position vector in space + + TVector3 GetTrackPos() const { return trackPos; } + TVector3 GetTrackVec() const { return trackVec; } + double GetTrackTheta() const { return trackVec.Theta(); } + double GetTrackPhi() const { return trackVec.Phi(); } + double GetZ0(); + + Coord Crossover[24][24][2]; + + + inline std::tuple, double, double, double> GetPseudoWire(const std::vector>& cluster, std::string type); + + inline std::tuple + FindCrossoverProperties(const std::vector>& a_cluster, const std::vector>& c_cluster); + + inline std::vector>> + Make_Clusters(std::unordered_map> wireEvents); + + int GetNumWire() const { return nWire; } + double GetDeltaAngle() const { return dAngle; } + double GetAnodeLength() const { return anodeLength; } + double GetCathodeLength() const { return cathodeLength; } + TVector3 GetAnodeDn(short id) const { return An[id].first; } + TVector3 GetAnodeUp(short id) const { return An[id].second; } + TVector3 GetCathodeDn(short id) const { return Ca[id].first; } + TVector3 GetCathodeUp(short id) const { return Ca[id].second; } + + TVector3 GetAnodneMid(short id) const { return (An[id].first + An[id].second) * 0.5; } + double GetAnodeTheta(short id) const { return (An[id].first - An[id].second).Theta(); } + double GetAnodePhi(short id) const { return (An[id].first - An[id].second).Phi(); } + + TVector3 GetCathodneMid(short id) const { return (Ca[id].first + Ca[id].second) * 0.5; } + double GetCathodeTheta(short id) const { return (Ca[id].first - Ca[id].second).Theta(); } + double GetCathodePhi(short id) const { return (Ca[id].first - Ca[id].second).Phi(); } + + void ClearHitInfo(); + void ConstructGeo(); + void FindWireID(TVector3 pos, TVector3 direction, bool verbose = false); + void CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose = false); + void CalTrack2(TVector3 sx3Pos, TVector3 anodeInt, bool verbose = false); + + void Print() + { + printf(" The nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nearestWire.first, + hitInfo.nearestDist.first, + hitInfo.nearestWire.second, + hitInfo.nearestDist.second); + + printf(" The 2nd nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nextNearestWire.first, + hitInfo.nextNearestDist.first, + hitInfo.nextNearestWire.second, + hitInfo.nextNearestDist.second); + } + +private: + PWHitInfo hitInfo; + + TVector3 trackPos; + TVector3 trackVec; + + const int nWire = 24; + const int wireShift = 3; + //const float zLen = 380; // mm +// const float zLen = 348.6; // mm + const float zLen = 174.3*2; // mm + const float radiusA = 37; + const float radiusC = 43; + + double dAngle; + double anodeLength; + double cathodeLength; + + // std::vector> An; // the anode wire position vector in space + // std::vector> Ca; // the cathode wire position vector in space + + double Distance(TVector3 a1, TVector3 a2, TVector3 b1, TVector3 b2) + { + TVector3 na = a1 - a2; + TVector3 nb = b1 - b2; + TVector3 nd = (na.Cross(nb)).Unit(); + return TMath::Abs(nd.Dot(a1 - b2)); + } +}; + +inline void PW::ClearHitInfo() +{ + hitInfo.Clear(); +} + +inline void PW::ConstructGeo() +{ + + An.clear(); + Ca.clear(); + + std::pair p1; // anode + std::pair q1; // cathode + + double k = TMath::TwoPi()/24.; //48 solder thru holes, wires in every other one + double offset_a1 = -6*k-3*k; + double offset_c1 = -4*k -2*k - TMath::TwoPi()/48; //correct for a half-turn + //std::cerr << "Here!" << std::endl; +//#include "../scratch/testing.h" + double offset_a2 = offset_a1+wireShift*k; + double offset_c2 = offset_c1-wireShift*k; + + for (int i = 0; i < nWire; i++) + { + // Anode rotate right-hand coming in towards +z riding with the beam. In this frame, +x is to the right, and +y down + //updated Feb 2026, Sudarsan B. Photographs indicate that anode wires twist right handed, as one moves from -z to +z with the convention above + //wire indices increase leftward as one moves to +z (hence -k factor), but wires themselves twist rightward - as indicated by offset_a2 being more +ve w.r.t offset_a1 + //'First' is -z locus, 'second' is +z locus + p1.first.SetXYZ(radiusA * TMath::Cos(-k*i + offset_a1), + radiusA * TMath::Sin(-k*i + offset_a1), + -zLen / 2); + p1.second.SetXYZ(radiusA * TMath::Cos(-k*i + offset_a2), + radiusA * TMath::Sin(-k*i + offset_a2), + +zLen / 2); + + // Cathodes twist left-hand as indicated by offset_c2 being more negative than offset_c1, under the same system, while wires increase rightward (hence +k factor) + q1.first.SetXYZ(radiusC * TMath::Cos(k*i + offset_c1), + radiusC * TMath::Sin(k*i + offset_c1), + -zLen / 2); + q1.second.SetXYZ(radiusC * TMath::Cos(k*i + offset_c2), + radiusC * TMath::Sin(k*i + offset_c2), + zLen / 2); + An.push_back(p1); + Ca.push_back(q1); + } + + + // Calculate Crossover Geometry ONCE + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha; + + for (size_t i = 0; i < An.size(); i++) + { + //a = An[i].first - An[i].second; + a = An[i].second - An[i].first; + for (size_t j = 0; j < Ca.size(); j++) + { + c = Ca[j].second- Ca[j].first; + diff = An[i].second - Ca[j].second; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + + Crossover[i][j][0].x = An[i].second.X() + alpha * a.X(); + Crossover[i][j][0].y = An[i].second.Y() + alpha * a.Y(); + Crossover[i][j][0].z = An[i].second.Z() + alpha * a.Z(); + + if(Crossover[i][j][0].z < -190 || Crossover[i][j][0].z > 190) { + //std::cout << "Weird crossover but ok" << std::endl; + } + if ( (i+j)%24 == 12 || Crossover[i][j][0].z < -190 || Crossover[i][j][0].z > 190) { + Crossover[i][j][0].z = 9999999; + //std::cout << "Weird crossover" << std::endl; + } + + Crossover[i][j][1].x = alpha; + Crossover[i][j][1].y = 0; + } + } + + + dAngle = wireShift * TMath::TwoPi() / nWire; + anodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusA * TMath::Sin(dAngle / 2), 2)); + cathodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusC * TMath::Sin(dAngle / 2), 2)); //chord length subtending an angle alpha is 2rsin(alpha/2) +} + +inline std::vector>> +PW::Make_Clusters(std::unordered_map> wireEvents) { + std::vector>> wireClusters; + std::vector> wireCluster; + //TODO: Write a macro once, call it twice + int wirecount=0; + while(wirecount < 24) { + if(wireEvents.find(wirecount)==wireEvents.end()) { + wirecount++; + continue; + } + wireCluster.clear(); + int ctr2=wirecount; + do { + wireCluster.emplace_back(wireEvents[ctr2]); + ctr2+=1; + if(ctr2==24 || ctr2-wirecount == 7) break; //loose logic, needs to be looked at. + } while(wireEvents.find(ctr2)!=wireEvents.end()); + wireClusters.push_back(std::move(wireCluster)); + wirecount = ctr2; //we already dealt with wires until the last value of ctr2 + } + + if(wireClusters.size() > 1) { //Deal with wraparound if required + auto first_cluster = wireClusters.front(); //front and back provide references to the elements themselves. less copy, can modify etc + auto last_cluster = wireClusters.back(); + if(std::get<0>(last_cluster.back())==23 && std::get<0>(first_cluster.front())==0) { + last_cluster.insert(last_cluster.end(),first_cluster.begin(),first_cluster.end()); + } + wireClusters.erase(wireClusters.begin()); //canonically, erase() needs an iterator, hence begin() not front() + //TODO: Can also deal with 'gaps' of missing wires similarly. end of one segment and beginning of another segment will be separated by missing wire --> combine the two + //TODO: Also needs some development regarding the time-correlation. Don't put wires in the same cluster if they aren't time coincident + } + return wireClusters; + + /*if(aClusters.size()>1 || cClusters.size() > 1) { + std::cout << " ============== " << std::endl; + } + if(aClusters.size()>1 && cClusters.size() >=1) { + std::cout << aClusters.size() << " new anode clusters ----> " << std::endl; + int cc=1; + for(auto ac : aClusters) { + std::cout << " Cluster " << cc << std::endl; + double first_ts = std::get<2>(ac.at(0)); + for(auto item : ac) { + std::cout << " \t" << std::get<0>(item) << " " << std::get<1>(item) << " " << std::get<2>(item)-first_ts << std::endl; + } + std::cout << " ------" << std::endl; + cc++; + } + } + + if(cClusters.size()>=1 ) { + std::cout << cClusters.size() << " new cathode clusters ----> " << std::endl; + int cc=1; + for(auto ac : cClusters) { + std::cout << " Cluster " << cc << std::endl; + double first_ts = std::get<2>(ac.at(0)); + for(auto item : ac) { + std::cout << " \t" << std::get<0>(item) << " " << std::get<1>(item) << " " << std::get<2>(item)-first_ts << std::endl; + } + std::cout << " ------" << std::endl; + cc++; + } + } */ +} + +inline std::tuple, double, double, double> +PW::GetPseudoWire(const std::vector>& cluster, std::string type) { + std::pair avgvec = std::pair(TVector3(0,0,0),TVector3(0,0,0)); + double sumEnergy = 0; + double maxEnergy = 0; + double tsMaxEnergy = 0; + if(type=="ANODE") { + //if(cluster.size()>1) std::cout << " -------anodes" << std::endl; + for( auto wire : cluster) { + avgvec.first += std::get<1>(wire)*TVector3(An.at(std::get<0>(wire)).first.X(), An.at(std::get<0>(wire)).first.Y(), 0) ; + avgvec.second += std::get<1>(wire)*TVector3(An.at(std::get<0>(wire)).second.X(), An.at(std::get<0>(wire)).second.Y(), 0); + sumEnergy += std::get<1>(wire); + if(std::get<1>(wire) > maxEnergy) { + maxEnergy = std::get<1>(wire); + tsMaxEnergy = std::get<2>(wire); + } + /*if(cluster.size()>1) { + std::cout << "\t\t ch:" << std::get<0>(wire) << " " << std::get<1>(wire) << " " << std::get<2>(wire) << std::endl; + std::cout << "\t\t w1(r,phi,z):" << An.at(std::get<0>(wire)).first.Perp() << " " << An.at(std::get<0>(wire)).first.Phi()*180/M_PI << " " << An.at(std::get<0>(wire)).first.Z() << std::endl; + std::cout << "\t\t w2(r,phi,z):" << An.at(std::get<0>(wire)).second.Perp() << " " << An.at(std::get<0>(wire)).second.Phi()*180/M_PI << " " << An.at(std::get<0>(wire)).second.Z() << std::endl; + }*/ + } + avgvec.first = avgvec.first*(1.0/sumEnergy); + avgvec.second = avgvec.second*(1.0/sumEnergy); + double phi1 = avgvec.first.Phi(); + double phi2 = avgvec.second.Phi(); + avgvec.first.SetXYZ(radiusA*TMath::Cos(phi1), radiusA*TMath::Sin(phi1), -zLen/2); + avgvec.second.SetXYZ(radiusA*TMath::Cos(phi2), radiusA*TMath::Sin(phi2), zLen/2); + /*if(cluster.size()>1) { + std::cout << "\t\t avg1(r,phi,z):" << avgvec.first.Perp() << " " << avgvec.first.Phi()*180/M_PI << " " << avgvec.first.Z() << std::endl; + std::cout << "\t\t avg2(r,phi,z):" << avgvec.second.Perp() << " " << avgvec.second.Phi()*180/M_PI << " " << avgvec.second.Z() << std::endl; + }*/ + } else if(type =="CATHODE") { + for( auto wire : cluster) { + avgvec.first += std::get<1>(wire)*TVector3(Ca.at(std::get<0>(wire)).first.X(), Ca.at(std::get<0>(wire)).first.Y(), 0) ; + avgvec.second += std::get<1>(wire)*TVector3(Ca.at(std::get<0>(wire)).second.X(), Ca.at(std::get<0>(wire)).second.Y(), 0); + sumEnergy += std::get<1>(wire); + if(std::get<1>(wire) > maxEnergy) { + maxEnergy = std::get<1>(wire); + tsMaxEnergy = std::get<2>(wire); + } + } + avgvec.first = avgvec.first*(1.0/sumEnergy); + avgvec.second = avgvec.second*(1.0/sumEnergy); + double phi1 = avgvec.first.Phi(); + double phi2 = avgvec.second.Phi(); + avgvec.first.SetXYZ(radiusC*TMath::Cos(phi1), radiusC*TMath::Sin(phi1), -zLen/2); + avgvec.second.SetXYZ(radiusC*TMath::Cos(phi2), radiusC*TMath::Sin(phi2), zLen/2); + } + return std::tuple(avgvec, sumEnergy, maxEnergy, tsMaxEnergy); +} + +inline std::tuple PW::FindCrossoverProperties(const std::vector>& a_cluster, + const std::vector>& c_cluster) { + //std::pair apwire = GetPseudoWire(a_cluster,"ANODE",anodeSumE); + //std::pair cpwire = GetPseudoWire(c_cluster,"CATHODE",cathodeSumE); + auto [apwire, apSumE, apMaxE, apTSMaxE] = GetPseudoWire(a_cluster,"ANODE"); + auto [cpwire, cpSumE, cpMaxE, cpTSMaxE] = GetPseudoWire(c_cluster,"CATHODE"); + + TVector3 crossover; + crossover.Clear(); + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha=0; + + if(apSumE && cpSumE) { + a = apwire.first - apwire.second; + c = cpwire.first - cpwire.second; + diff = apwire.first- cpwire.first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + crossover = apwire.first + alpha*a; + if(crossover.z() < -190 || crossover.Z() > 190 ) { + alpha = 9999999; + apSumE=-1; cpSumE=-1; + apMaxE=-1; cpMaxE=-1; + apTSMaxE=-1; cpTSMaxE=-1; + } + } + //std::cout << apSumE << " " << cpSumE << " " << " " << crossover.Perp() << std::endl; + return std::tuple(crossover,alpha,apSumE,cpSumE,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE); +} + +inline void PW::FindWireID(TVector3 pos, TVector3 direction, bool verbose) +{ + + hitInfo.Clear(); + double phi = direction.Phi(); + + for (int i = 0; i < nWire; i++) + { + + double disA = 99999999; + double phiS = An[i].first.Phi() - TMath::PiOver4(); + double phiL = An[i].second.Phi() + TMath::PiOver4(); + // printf("A%2d: %f %f | %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg(), phi * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disA = Distance(pos, pos + direction, An[i].first, An[i].second); + if (disA < hitInfo.nearestDist.first) + { + hitInfo.nearestDist.first = disA; + hitInfo.nearestWire.first = i; + } + } + + double disC = 99999999; + phiS = Ca[i].second.Phi() - TMath::PiOver4(); + phiL = Ca[i].first.Phi() + TMath::PiOver4(); + // printf("C%2d: %f %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disC = Distance(pos, pos + direction, Ca[i].first, Ca[i].second); + if (disC < hitInfo.nearestDist.second) + { + hitInfo.nearestDist.second = disC; + hitInfo.nearestWire.second = i; + } + } + + if (verbose) + printf(" %2d | %8.2f, %8.2f\n", i, disA, disC); + } + + //==== find the 2nd nearest wire + short anode1 = hitInfo.nearestWire.first; + short aaa1 = anode1 - 1; + if (aaa1 < 0) + aaa1 += nWire; + short aaa2 = (anode1 + 1) % nWire; + + double haha1 = Distance(pos, pos + direction, An[aaa1].first, An[aaa1].second); + double haha2 = Distance(pos, pos + direction, An[aaa2].first, An[aaa2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.first = aaa1; + hitInfo.nextNearestDist.first = haha1; + } + else + { + hitInfo.nextNearestWire.first = aaa2; + hitInfo.nextNearestDist.first = haha2; + } + + short cathode1 = hitInfo.nearestWire.second; + short ccc1 = cathode1 - 1; + if (ccc1 < 0) + ccc1 += nWire; + short ccc2 = (cathode1 + 1) % nWire; + + haha1 = Distance(pos, pos + direction, Ca[ccc1].first, Ca[ccc1].second); + haha2 = Distance(pos, pos + direction, Ca[ccc2].first, Ca[ccc2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.second = ccc1; + hitInfo.nextNearestDist.second = haha1; + } + else + { + hitInfo.nextNearestWire.second = ccc2; + hitInfo.nextNearestDist.second = haha2; + } + + if (verbose) + Print(); +} + +inline void PW::CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose) +{ + + trackPos = sx3Pos; + + TVector3 n1 = (An[anodeID].first - An[anodeID].second).Cross((sx3Pos - An[anodeID].second)).Unit(); + TVector3 n2 = (Ca[cathodeID].first - Ca[cathodeID].second).Cross((sx3Pos - Ca[cathodeID].second)).Unit(); + + // if the handiness of anode and cathode revered, it should be n2 cross n1 + trackVec = (n2.Cross(n1)).Unit(); + + if (verbose) + printf("Theta, Phi = %f, %f \n", trackVec.Theta() * TMath::RadToDeg(), trackVec.Phi() * TMath::RadToDeg()); +} + + +inline void PW::CalTrack2(TVector3 siPos, TVector3 anodeInt, bool verbose) +{ + + double mx, my; + double z; + mx = siPos.X() / (siPos.X() - anodeInt.X()); + my = siPos.Y() / (siPos.Y() - anodeInt.Y()); + z=siPos.Z() + mx * (anodeInt.Z() - siPos.Z()); + // if (mx == my) + { + trackVec=TVector3(0,0,z); + } + + if (verbose) + printf("X slope = %f and Y slope = %f \n", mx, my); +} + +/*inline TVector3 PW::CalTrack3(TVector3 siPos, TVector3 anodeInt, bool verbose) +{ + + TVector3 v = anodeInt-siPos; + double t_minimum = -1.0*(siPos.X()*v.X()+siPos.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 vector_closest_to_z = siPos + t_minimum*v; + + return vector_closest_to_z; + if (verbose) + printf("X slope = %f and Y slope = %f \n", mx, my); +}*/ + +inline double PW::GetZ0() +{ + + double x = trackPos.X(); + double y = trackPos.Y(); + double rho = TMath::Sqrt(x * x + y * y); + double theta = trackVec.Theta(); + + return trackVec.Z(); +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/ClassPW.h.Questionable.Feb2026 b/anasen_analysis_vignesh/Armory/ClassPW.h.Questionable.Feb2026 new file mode 100644 index 0000000..ebe083a --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassPW.h.Questionable.Feb2026 @@ -0,0 +1,491 @@ +#ifndef ClassPW_h +#define ClassPW_h + +#include +#include +#include +#include +#include + +struct PWHitInfo +{ + std::pair nearestWire; // anode, cathode + std::pair nearestDist; // anode, cathode + + std::pair nextNearestWire; // anode, cathode + std::pair nextNearestDist; // anode, cathode + + void Clear() + { + nearestWire.first = -1; + nearestWire.second = -1; + nearestDist.first = 999999999; + nearestDist.second = 999999999; + nextNearestWire.first = -1; + nextNearestWire.second = -1; + nextNearestDist.first = 999999999; + nextNearestDist.second = 999999999; + } +}; + +struct Coord +{ + float x, y, z; + Coord() : x(0), y(0), z(0) {} + Coord(const TVector3 &vec) + { + x = vec.X(); // TVector3's X() returns the x-coordinate + y = vec.Y(); // TVector3's Y() returns the y-coordinate + z = vec.Z(); // TVector3's Z() returns the z-coordinate + } +}; + +//! ######################################################## +class PW +{ // proportional wire +public: + PW() { ClearHitInfo(); }; + ~PW() {}; + + PWHitInfo GetHitInfo() const { return hitInfo; } + std::pair GetNearestID() const { return hitInfo.nearestWire; } + std::pair GetNearestDistance() const { return hitInfo.nearestDist; } + std::pair Get2ndNearestID() const { return hitInfo.nextNearestWire; } + std::pair Get2ndNearestDistance() const { return hitInfo.nextNearestDist; } + + std::vector> An; // the anode wire position vector in space + std::vector> Ca; // the cathode wire position vector in space + + TVector3 GetTrackPos() const { return trackPos; } + TVector3 GetTrackVec() const { return trackVec; } + double GetTrackTheta() const { return trackVec.Theta(); } + double GetTrackPhi() const { return trackVec.Phi(); } + double GetZ0(); + + inline std::tuple, double, double, double> GetPseudoWire(const std::vector>& cluster, std::string type); + + inline std::tuple + FindCrossoverProperties(const std::vector>& a_cluster, const std::vector>& c_cluster); + + inline std::vector>> + Make_Clusters(std::unordered_map> wireEvents); + + int GetNumWire() const { return nWire; } + double GetDeltaAngle() const { return dAngle; } + double GetAnodeLength() const { return anodeLength; } + double GetCathodeLength() const { return cathodeLength; } + TVector3 GetAnodeDn(short id) const { return An[id].first; } + TVector3 GetAnodeUp(short id) const { return An[id].second; } + TVector3 GetCathodeDn(short id) const { return Ca[id].first; } + TVector3 GetCathodeUp(short id) const { return Ca[id].second; } + + TVector3 GetAnodneMid(short id) const { return (An[id].first + An[id].second) * 0.5; } + double GetAnodeTheta(short id) const { return (An[id].first - An[id].second).Theta(); } + double GetAnodePhi(short id) const { return (An[id].first - An[id].second).Phi(); } + + TVector3 GetCathodneMid(short id) const { return (Ca[id].first + Ca[id].second) * 0.5; } + double GetCathodeTheta(short id) const { return (Ca[id].first - Ca[id].second).Theta(); } + double GetCathodePhi(short id) const { return (Ca[id].first - Ca[id].second).Phi(); } + + void ClearHitInfo(); + void ConstructGeo(); + void FindWireID(TVector3 pos, TVector3 direction, bool verbose = false); + void CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose = false); + void CalTrack2(TVector3 sx3Pos, TVector3 anodeInt, bool verbose = false); + + void Print() + { + printf(" The nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nearestWire.first, + hitInfo.nearestDist.first, + hitInfo.nearestWire.second, + hitInfo.nearestDist.second); + + printf(" The 2nd nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nextNearestWire.first, + hitInfo.nextNearestDist.first, + hitInfo.nextNearestWire.second, + hitInfo.nextNearestDist.second); + } + +private: + PWHitInfo hitInfo; + + TVector3 trackPos; + TVector3 trackVec; + + const int nWire = 24; + const int wireShift = 3; + //const float zLen = 380; // mm + const float zLen = 348.6; // mm + const float radiusA = 37; + const float radiusC = 43; + + double dAngle; + double anodeLength; + double cathodeLength; + + // std::vector> An; // the anode wire position vector in space + // std::vector> Ca; // the cathode wire position vector in space + + double Distance(TVector3 a1, TVector3 a2, TVector3 b1, TVector3 b2) + { + TVector3 na = a1 - a2; + TVector3 nb = b1 - b2; + TVector3 nd = (na.Cross(nb)).Unit(); + return TMath::Abs(nd.Dot(a1 - b2)); + } +}; + +inline void PW::ClearHitInfo() +{ + hitInfo.Clear(); +} + +inline void PW::ConstructGeo() +{ + + An.clear(); + Ca.clear(); + + std::pair p1; // anode + std::pair q1; // cathode + + // anode and cathode start at pos-Y axis and count in right-Hand + // anode wire shift is right-hand. + // cathode wire shift is left-hand. + + for (int i = 0; i < nWire; i++) + { + // Anode rotate right-hand + //updated Feb 2026, Sudarsan B + p1.first.SetXYZ(radiusA * TMath::Cos(TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + radiusA * TMath::Sin(TMath::TwoPi() / nWire * (i) + TMath::PiOver2()), + zLen / 2); + p1.second.SetXYZ(radiusA * TMath::Cos(TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + radiusA * TMath::Sin(TMath::TwoPi() / nWire * (i + wireShift) + TMath::PiOver2()), + -zLen / 2); + An.push_back(p1); + + // Cathod rotate left-hand with the 3 wire offset accounted for (+1 from the calculated offset from the PC coincidence spectrum) + q1.first.SetXYZ(radiusC * TMath::Cos(TMath::TwoPi() / nWire * (i + wireShift + 1) + TMath::PiOver2()), + radiusC * TMath::Sin(TMath::TwoPi() / nWire * (i + wireShift + 1) + TMath::PiOver2()), + zLen / 2); + q1.second.SetXYZ(radiusC * TMath::Cos(TMath::TwoPi() / nWire * (i + 1) + TMath::PiOver2()), + radiusC * TMath::Sin(TMath::TwoPi() / nWire * (i + 1) + TMath::PiOver2()), + -zLen / 2); + Ca.push_back(q1); + } + // correcting for the fact that the order of the cathode wires is reversed + std::reverse(Ca.begin(), Ca.end()); + // adjusting for the 3 wire offset, the rbegin and rend are used as the rotation of the wires is done in the opposite direction i.e. 1,2,3 -> 3,1,2 + // NOT NECESSARY ANY MORE, HAS BEEN IMCORPORATED INTO THE WIREOFFSET IN THE BEGINNING + // std::rotate(Ca.rbegin(), Ca.rbegin() + 4, Ca.rend()); + + dAngle = wireShift * TMath::TwoPi() / nWire; + anodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusA * TMath::Sin(dAngle / 2), 2)); + cathodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusC * TMath::Sin(dAngle / 2), 2)); //chord length subtending an angle alpha is 2rsin(alpha/2) +} + +inline std::vector>> +PW::Make_Clusters(std::unordered_map> wireEvents) { + std::vector>> wireClusters; + std::vector> wireCluster; + //TODO: Write a macro once, call it twice + int wirecount=0; + while(wirecount < 24) { + if(wireEvents.find(wirecount)==wireEvents.end()) { + wirecount++; + continue; + } + wireCluster.clear(); + int ctr2=wirecount; + do { + wireCluster.emplace_back(wireEvents[ctr2]); + ctr2+=1; + if(ctr2==24 || ctr2-wirecount == 7) break; //loose logic, needs to be looked at. + } while(wireEvents.find(ctr2)!=wireEvents.end()); + wireClusters.push_back(std::move(wireCluster)); + wirecount = ctr2; //we already dealt with wires until the last value of ctr2 + } + + if(wireClusters.size() > 1) { //Deal with wraparound if required + auto first_cluster = wireClusters.front(); //front and back provide references to the elements themselves. less copy, can modify etc + auto last_cluster = wireClusters.back(); + if(std::get<0>(last_cluster.back())==23 && std::get<0>(first_cluster.front())==0) { + last_cluster.insert(last_cluster.end(),first_cluster.begin(),first_cluster.end()); + } + wireClusters.erase(wireClusters.begin()); //canonically, erase() needs an iterator, hence begin() not front() + //TODO: Can also deal with 'gaps' of missing wires similarly. end of one segment and beginning of another segment will be separated by missing wire --> combine the two + //TODO: Also needs some development regarding the time-correlation. Don't put wires in the same cluster if they aren't time coincident + } + return wireClusters; + + /*if(aClusters.size()>1 || cClusters.size() > 1) { + std::cout << " ============== " << std::endl; + } + if(aClusters.size()>1 && cClusters.size() >=1) { + std::cout << aClusters.size() << " new anode clusters ----> " << std::endl; + int cc=1; + for(auto ac : aClusters) { + std::cout << " Cluster " << cc << std::endl; + double first_ts = std::get<2>(ac.at(0)); + for(auto item : ac) { + std::cout << " \t" << std::get<0>(item) << " " << std::get<1>(item) << " " << std::get<2>(item)-first_ts << std::endl; + } + std::cout << " ------" << std::endl; + cc++; + } + } + + if(cClusters.size()>=1 ) { + std::cout << cClusters.size() << " new cathode clusters ----> " << std::endl; + int cc=1; + for(auto ac : cClusters) { + std::cout << " Cluster " << cc << std::endl; + double first_ts = std::get<2>(ac.at(0)); + for(auto item : ac) { + std::cout << " \t" << std::get<0>(item) << " " << std::get<1>(item) << " " << std::get<2>(item)-first_ts << std::endl; + } + std::cout << " ------" << std::endl; + cc++; + } + } */ +} + +inline std::tuple, double, double, double> +PW::GetPseudoWire(const std::vector>& cluster, std::string type) { + std::pair avgvec = std::pair(TVector3(0,0,0),TVector3(0,0,0)); + double sumEnergy = 0; + double maxEnergy = 0; + double tsMaxEnergy = 0; + if(type=="ANODE") { + //if(cluster.size()>1) std::cout << " -------anodes" << std::endl; + for( auto wire : cluster) { + avgvec.first += std::get<1>(wire)*TVector3(An.at(std::get<0>(wire)).first.X(), An.at(std::get<0>(wire)).first.Y(), 0) ; + avgvec.second += std::get<1>(wire)*TVector3(An.at(std::get<0>(wire)).second.X(), An.at(std::get<0>(wire)).second.Y(), 0); + sumEnergy += std::get<1>(wire); + if(std::get<1>(wire) > maxEnergy) { + maxEnergy = std::get<1>(wire); + tsMaxEnergy = std::get<2>(wire); + } + /*if(cluster.size()>1) { + std::cout << "\t\t ch:" << std::get<0>(wire) << " " << std::get<1>(wire) << " " << std::get<2>(wire) << std::endl; + std::cout << "\t\t w1(r,phi,z):" << An.at(std::get<0>(wire)).first.Perp() << " " << An.at(std::get<0>(wire)).first.Phi()*180/M_PI << " " << An.at(std::get<0>(wire)).first.Z() << std::endl; + std::cout << "\t\t w2(r,phi,z):" << An.at(std::get<0>(wire)).second.Perp() << " " << An.at(std::get<0>(wire)).second.Phi()*180/M_PI << " " << An.at(std::get<0>(wire)).second.Z() << std::endl; + }*/ + } + avgvec.first = avgvec.first*(1.0/sumEnergy); + avgvec.second = avgvec.second*(1.0/sumEnergy); + double phi1 = avgvec.first.Phi(); + double phi2 = avgvec.second.Phi(); + avgvec.first.SetXYZ(radiusA*TMath::Cos(phi1), radiusA*TMath::Sin(phi1), zLen/2); + avgvec.second.SetXYZ(radiusA*TMath::Cos(phi2), radiusA*TMath::Sin(phi2), -zLen/2); + /*if(cluster.size()>1) { + std::cout << "\t\t avg1(r,phi,z):" << avgvec.first.Perp() << " " << avgvec.first.Phi()*180/M_PI << " " << avgvec.first.Z() << std::endl; + std::cout << "\t\t avg2(r,phi,z):" << avgvec.second.Perp() << " " << avgvec.second.Phi()*180/M_PI << " " << avgvec.second.Z() << std::endl; + }*/ + } else if(type =="CATHODE") { + for( auto wire : cluster) { + avgvec.first += std::get<1>(wire)*TVector3(Ca.at(std::get<0>(wire)).first.X(), Ca.at(std::get<0>(wire)).first.Y(), 0) ; + avgvec.second += std::get<1>(wire)*TVector3(Ca.at(std::get<0>(wire)).second.X(), Ca.at(std::get<0>(wire)).second.Y(), 0); + sumEnergy += std::get<1>(wire); + if(std::get<1>(wire) > maxEnergy) { + maxEnergy = std::get<1>(wire); + tsMaxEnergy = std::get<2>(wire); + } + } + avgvec.first = avgvec.first*(1.0/sumEnergy); + avgvec.second = avgvec.second*(1.0/sumEnergy); + double phi1 = avgvec.first.Phi(); + double phi2 = avgvec.second.Phi(); + avgvec.first.SetXYZ(radiusC*TMath::Cos(phi1), radiusC*TMath::Sin(phi1), zLen/2); + avgvec.second.SetXYZ(radiusC*TMath::Cos(phi2), radiusC*TMath::Sin(phi2), -zLen/2); + } + return std::tuple(avgvec, sumEnergy, maxEnergy, tsMaxEnergy); +} + +inline std::tuple PW::FindCrossoverProperties(const std::vector>& a_cluster, + const std::vector>& c_cluster) { + //std::pair apwire = GetPseudoWire(a_cluster,"ANODE",anodeSumE); + //std::pair cpwire = GetPseudoWire(c_cluster,"CATHODE",cathodeSumE); + auto [apwire, apSumE, apMaxE, apTSMaxE] = GetPseudoWire(a_cluster,"ANODE"); + auto [cpwire, cpSumE, cpMaxE, cpTSMaxE] = GetPseudoWire(c_cluster,"CATHODE"); + + TVector3 crossover; + crossover.Clear(); + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha=0; + + if(apSumE && cpSumE) { + a = apwire.first - apwire.second; + c = cpwire.first - cpwire.second; + diff = apwire.first - cpwire.first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + crossover = apwire.first + alpha*a; + if(crossover.z() < -190 || crossover.Z() > 190 ) { + alpha = 9999999; + apSumE=-1; cpSumE=-1; + apMaxE=-1; cpMaxE=-1; + apTSMaxE=-1; cpTSMaxE=-1; + } + } + //std::cout << apSumE << " " << cpSumE << " " << " " << crossover.Perp() << std::endl; + return std::tuple(crossover,alpha,apSumE,cpSumE,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE); +} + +inline void PW::FindWireID(TVector3 pos, TVector3 direction, bool verbose) +{ + + hitInfo.Clear(); + double phi = direction.Phi(); + + for (int i = 0; i < nWire; i++) + { + + double disA = 99999999; + double phiS = An[i].first.Phi() - TMath::PiOver4(); + double phiL = An[i].second.Phi() + TMath::PiOver4(); + // printf("A%2d: %f %f | %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg(), phi * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disA = Distance(pos, pos + direction, An[i].first, An[i].second); + if (disA < hitInfo.nearestDist.first) + { + hitInfo.nearestDist.first = disA; + hitInfo.nearestWire.first = i; + } + } + + double disC = 99999999; + phiS = Ca[i].second.Phi() - TMath::PiOver4(); + phiL = Ca[i].first.Phi() + TMath::PiOver4(); + // printf("C%2d: %f %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disC = Distance(pos, pos + direction, Ca[i].first, Ca[i].second); + if (disC < hitInfo.nearestDist.second) + { + hitInfo.nearestDist.second = disC; + hitInfo.nearestWire.second = i; + } + } + + if (verbose) + printf(" %2d | %8.2f, %8.2f\n", i, disA, disC); + } + + //==== find the 2nd nearest wire + short anode1 = hitInfo.nearestWire.first; + short aaa1 = anode1 - 1; + if (aaa1 < 0) + aaa1 += nWire; + short aaa2 = (anode1 + 1) % nWire; + + double haha1 = Distance(pos, pos + direction, An[aaa1].first, An[aaa1].second); + double haha2 = Distance(pos, pos + direction, An[aaa2].first, An[aaa2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.first = aaa1; + hitInfo.nextNearestDist.first = haha1; + } + else + { + hitInfo.nextNearestWire.first = aaa2; + hitInfo.nextNearestDist.first = haha2; + } + + short cathode1 = hitInfo.nearestWire.second; + short ccc1 = cathode1 - 1; + if (ccc1 < 0) + ccc1 += nWire; + short ccc2 = (cathode1 + 1) % nWire; + + haha1 = Distance(pos, pos + direction, Ca[ccc1].first, Ca[ccc1].second); + haha2 = Distance(pos, pos + direction, Ca[ccc2].first, Ca[ccc2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.second = ccc1; + hitInfo.nextNearestDist.second = haha1; + } + else + { + hitInfo.nextNearestWire.second = ccc2; + hitInfo.nextNearestDist.second = haha2; + } + + if (verbose) + Print(); +} + +inline void PW::CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose) +{ + + trackPos = sx3Pos; + + TVector3 n1 = (An[anodeID].first - An[anodeID].second).Cross((sx3Pos - An[anodeID].second)).Unit(); + TVector3 n2 = (Ca[cathodeID].first - Ca[cathodeID].second).Cross((sx3Pos - Ca[cathodeID].second)).Unit(); + + // if the handiness of anode and cathode revered, it should be n2 cross n1 + trackVec = (n2.Cross(n1)).Unit(); + + if (verbose) + printf("Theta, Phi = %f, %f \n", trackVec.Theta() * TMath::RadToDeg(), trackVec.Phi() * TMath::RadToDeg()); +} + + +inline void PW::CalTrack2(TVector3 siPos, TVector3 anodeInt, bool verbose) +{ + + double mx, my; + double z; + mx = siPos.X() / (siPos.X() - anodeInt.X()); + my = siPos.Y() / (siPos.Y() - anodeInt.Y()); + z=siPos.Z() + mx * (anodeInt.Z() - siPos.Z()); + // if (mx == my) + { + trackVec=TVector3(0,0,z); + } + + if (verbose) + printf("X slope = %f and Y slope = %f \n", mx, my); +} + +/*inline TVector3 PW::CalTrack3(TVector3 siPos, TVector3 anodeInt, bool verbose) +{ + + TVector3 v = anodeInt-siPos; + double t_minimum = -1.0*(siPos.X()*v.X()+siPos.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 vector_closest_to_z = siPos + t_minimum*v; + + return vector_closest_to_z; + if (verbose) + printf("X slope = %f and Y slope = %f \n", mx, my); +}*/ + +inline double PW::GetZ0() +{ + + double x = trackPos.X(); + double y = trackPos.Y(); + double rho = TMath::Sqrt(x * x + y * y); + double theta = trackVec.Theta(); + + return trackVec.Z(); +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/ClassPW.h.modified b/anasen_analysis_vignesh/Armory/ClassPW.h.modified new file mode 100644 index 0000000..fa3d319 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassPW.h.modified @@ -0,0 +1,489 @@ +#ifndef ClassPW_h +#define ClassPW_h + +#include +#include +#include +#include +#include + +struct PWHitInfo +{ + std::pair nearestWire; // anode, cathode + std::pair nearestDist; // anode, cathode + + std::pair nextNearestWire; // anode, cathode + std::pair nextNearestDist; // anode, cathode + + void Clear() + { + nearestWire.first = -1; + nearestWire.second = -1; + nearestDist.first = 999999999; + nearestDist.second = 999999999; + nextNearestWire.first = -1; + nextNearestWire.second = -1; + nextNearestDist.first = 999999999; + nextNearestDist.second = 999999999; + } +}; + +struct Coord +{ + float x, y, z; + Coord() : x(0), y(0), z(0) {} + Coord(const TVector3 &vec) + { + x = vec.X(); // TVector3's X() returns the x-coordinate + y = vec.Y(); // TVector3's Y() returns the y-coordinate + z = vec.Z(); // TVector3's Z() returns the z-coordinate + } +}; + +//! ######################################################## +class PW +{ // proportional wire +public: + PW() { ClearHitInfo(); }; + ~PW() {}; + + PWHitInfo GetHitInfo() const { return hitInfo; } + std::pair GetNearestID() const { return hitInfo.nearestWire; } + std::pair GetNearestDistance() const { return hitInfo.nearestDist; } + std::pair Get2ndNearestID() const { return hitInfo.nextNearestWire; } + std::pair Get2ndNearestDistance() const { return hitInfo.nextNearestDist; } + + std::vector> An; // the anode wire position vector in space + std::vector> Ca; // the cathode wire position vector in space + + TVector3 GetTrackPos() const { return trackPos; } + TVector3 GetTrackVec() const { return trackVec; } + double GetTrackTheta() const { return trackVec.Theta(); } + double GetTrackPhi() const { return trackVec.Phi(); } + double GetZ0(); + + inline std::tuple, double, double, double> GetPseudoWire(const std::vector>& cluster, std::string type); + + inline std::tuple + FindCrossoverProperties(const std::vector>& a_cluster, const std::vector>& c_cluster); + + inline std::vector>> + Make_Clusters(std::unordered_map> wireEvents); + + int GetNumWire() const { return nWire; } + double GetDeltaAngle() const { return dAngle; } + double GetAnodeLength() const { return anodeLength; } + double GetCathodeLength() const { return cathodeLength; } + TVector3 GetAnodeDn(short id) const { return An[id].first; } + TVector3 GetAnodeUp(short id) const { return An[id].second; } + TVector3 GetCathodeDn(short id) const { return Ca[id].first; } + TVector3 GetCathodeUp(short id) const { return Ca[id].second; } + + TVector3 GetAnodneMid(short id) const { return (An[id].first + An[id].second) * 0.5; } + double GetAnodeTheta(short id) const { return (An[id].first - An[id].second).Theta(); } + double GetAnodePhi(short id) const { return (An[id].first - An[id].second).Phi(); } + + TVector3 GetCathodneMid(short id) const { return (Ca[id].first + Ca[id].second) * 0.5; } + double GetCathodeTheta(short id) const { return (Ca[id].first - Ca[id].second).Theta(); } + double GetCathodePhi(short id) const { return (Ca[id].first - Ca[id].second).Phi(); } + + void ClearHitInfo(); + void ConstructGeo(); + void FindWireID(TVector3 pos, TVector3 direction, bool verbose = false); + void CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose = false); + void CalTrack2(TVector3 sx3Pos, TVector3 anodeInt, bool verbose = false); + + void Print() + { + printf(" The nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nearestWire.first, + hitInfo.nearestDist.first, + hitInfo.nearestWire.second, + hitInfo.nearestDist.second); + + printf(" The 2nd nearest | Anode: %2d(%5.2f) Cathode: %2d(%5.2f)\n", hitInfo.nextNearestWire.first, + hitInfo.nextNearestDist.first, + hitInfo.nextNearestWire.second, + hitInfo.nextNearestDist.second); + } + +private: + PWHitInfo hitInfo; + + TVector3 trackPos; + TVector3 trackVec; + + const int nWire = 24; + const int wireShift = 3; + //const float zLen = 380; // mm + const float zLen = 348.6; // mm + const float radiusA = 37; + const float radiusC = 43; + + double dAngle; + double anodeLength; + double cathodeLength; + + // std::vector> An; // the anode wire position vector in space + // std::vector> Ca; // the cathode wire position vector in space + + double Distance(TVector3 a1, TVector3 a2, TVector3 b1, TVector3 b2) + { + TVector3 na = a1 - a2; + TVector3 nb = b1 - b2; + TVector3 nd = (na.Cross(nb)).Unit(); + return TMath::Abs(nd.Dot(a1 - b2)); + } +}; + +inline void PW::ClearHitInfo() +{ + hitInfo.Clear(); +} + +inline void PW::ConstructGeo() +{ + + An.clear(); + Ca.clear(); + + std::pair p1; // anode + std::pair q1; // cathode + + double k = TMath::TwoPi()/24.; //48 solder thru holes, wires in every other one + double offset_a1 = -6*k-3*k; + double offset_c1 = -3*k - TMath::TwoPi()/48; //correct for a half-turn + double offset_a2 = offset_a1+3*k; + double offset_c2 = offset_c1-3*k; + + for (int i = 0; i < nWire; i++) + { + // Anode rotate right-hand coming in towards +z riding with the beam. In this frame, +x is to the right, and +y down + //updated Feb 2026, Sudarsan B. Photographs indicate that anode wires twist right handed, as one moves from -z to +z with the convention above + //'First' is -z locus, 'second' is +z locus + p1.first.SetXYZ(radiusA * TMath::Cos(-k*i + offset_a1), + radiusA * TMath::Sin(-k*i + offset_a1), + -zLen / 2); + p1.second.SetXYZ(radiusA * TMath::Cos(-k*i + offset_a2), + radiusA * TMath::Sin(-k*i + offset_a2), + +zLen / 2); + + // Cathodes rotate left-hand, under the same system. k is positive + q1.first.SetXYZ(radiusC * TMath::Cos(k*i + offset_c1), + radiusC * TMath::Sin(k*i + offset_c1), + -zLen / 2); + q1.second.SetXYZ(radiusC * TMath::Cos(k*i + offset_c2), + radiusC * TMath::Sin(k*i + offset_c2), + zLen / 2); + An.push_back(p1); + Ca.push_back(q1); + } + + dAngle = wireShift * TMath::TwoPi() / nWire; + anodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusA * TMath::Sin(dAngle / 2), 2)); + cathodeLength = TMath::Sqrt(zLen * zLen + TMath::Power(2 * radiusC * TMath::Sin(dAngle / 2), 2)); //chord length subtending an angle alpha is 2rsin(alpha/2) +} + +inline std::vector>> +PW::Make_Clusters(std::unordered_map> wireEvents) { + std::vector>> wireClusters; + std::vector> wireCluster; + //TODO: Write a macro once, call it twice + int wirecount=0; + while(wirecount < 24) { + if(wireEvents.find(wirecount)==wireEvents.end()) { + wirecount++; + continue; + } + wireCluster.clear(); + int ctr2=wirecount; + do { + wireCluster.emplace_back(wireEvents[ctr2]); + ctr2+=1; + if(ctr2==24 || ctr2-wirecount == 7) break; //loose logic, needs to be looked at. + } while(wireEvents.find(ctr2)!=wireEvents.end()); + wireClusters.push_back(std::move(wireCluster)); + wirecount = ctr2; //we already dealt with wires until the last value of ctr2 + } + + if(wireClusters.size() > 1) { //Deal with wraparound if required + auto first_cluster = wireClusters.front(); //front and back provide references to the elements themselves. less copy, can modify etc + auto last_cluster = wireClusters.back(); + if(std::get<0>(last_cluster.back())==23 && std::get<0>(first_cluster.front())==0) { + last_cluster.insert(last_cluster.end(),first_cluster.begin(),first_cluster.end()); + } + wireClusters.erase(wireClusters.begin()); //canonically, erase() needs an iterator, hence begin() not front() + //TODO: Can also deal with 'gaps' of missing wires similarly. end of one segment and beginning of another segment will be separated by missing wire --> combine the two + //TODO: Also needs some development regarding the time-correlation. Don't put wires in the same cluster if they aren't time coincident + } + return wireClusters; + + /*if(aClusters.size()>1 || cClusters.size() > 1) { + std::cout << " ============== " << std::endl; + } + if(aClusters.size()>1 && cClusters.size() >=1) { + std::cout << aClusters.size() << " new anode clusters ----> " << std::endl; + int cc=1; + for(auto ac : aClusters) { + std::cout << " Cluster " << cc << std::endl; + double first_ts = std::get<2>(ac.at(0)); + for(auto item : ac) { + std::cout << " \t" << std::get<0>(item) << " " << std::get<1>(item) << " " << std::get<2>(item)-first_ts << std::endl; + } + std::cout << " ------" << std::endl; + cc++; + } + } + + if(cClusters.size()>=1 ) { + std::cout << cClusters.size() << " new cathode clusters ----> " << std::endl; + int cc=1; + for(auto ac : cClusters) { + std::cout << " Cluster " << cc << std::endl; + double first_ts = std::get<2>(ac.at(0)); + for(auto item : ac) { + std::cout << " \t" << std::get<0>(item) << " " << std::get<1>(item) << " " << std::get<2>(item)-first_ts << std::endl; + } + std::cout << " ------" << std::endl; + cc++; + } + } */ +} + +inline std::tuple, double, double, double> +PW::GetPseudoWire(const std::vector>& cluster, std::string type) { + std::pair avgvec = std::pair(TVector3(0,0,0),TVector3(0,0,0)); + double sumEnergy = 0; + double maxEnergy = 0; + double tsMaxEnergy = 0; + if(type=="ANODE") { + //if(cluster.size()>1) std::cout << " -------anodes" << std::endl; + for( auto wire : cluster) { + avgvec.first += std::get<1>(wire)*TVector3(An.at(std::get<0>(wire)).first.X(), An.at(std::get<0>(wire)).first.Y(), 0) ; + avgvec.second += std::get<1>(wire)*TVector3(An.at(std::get<0>(wire)).second.X(), An.at(std::get<0>(wire)).second.Y(), 0); + sumEnergy += std::get<1>(wire); + if(std::get<1>(wire) > maxEnergy) { + maxEnergy = std::get<1>(wire); + tsMaxEnergy = std::get<2>(wire); + } + /*if(cluster.size()>1) { + std::cout << "\t\t ch:" << std::get<0>(wire) << " " << std::get<1>(wire) << " " << std::get<2>(wire) << std::endl; + std::cout << "\t\t w1(r,phi,z):" << An.at(std::get<0>(wire)).first.Perp() << " " << An.at(std::get<0>(wire)).first.Phi()*180/M_PI << " " << An.at(std::get<0>(wire)).first.Z() << std::endl; + std::cout << "\t\t w2(r,phi,z):" << An.at(std::get<0>(wire)).second.Perp() << " " << An.at(std::get<0>(wire)).second.Phi()*180/M_PI << " " << An.at(std::get<0>(wire)).second.Z() << std::endl; + }*/ + } + avgvec.first = avgvec.first*(1.0/sumEnergy); + avgvec.second = avgvec.second*(1.0/sumEnergy); + double phi1 = avgvec.first.Phi(); + double phi2 = avgvec.second.Phi(); + avgvec.first.SetXYZ(radiusA*TMath::Cos(phi1), radiusA*TMath::Sin(phi1), -zLen/2); + avgvec.second.SetXYZ(radiusA*TMath::Cos(phi2), radiusA*TMath::Sin(phi2), zLen/2); + /*if(cluster.size()>1) { + std::cout << "\t\t avg1(r,phi,z):" << avgvec.first.Perp() << " " << avgvec.first.Phi()*180/M_PI << " " << avgvec.first.Z() << std::endl; + std::cout << "\t\t avg2(r,phi,z):" << avgvec.second.Perp() << " " << avgvec.second.Phi()*180/M_PI << " " << avgvec.second.Z() << std::endl; + }*/ + } else if(type =="CATHODE") { + for( auto wire : cluster) { + avgvec.first += std::get<1>(wire)*TVector3(Ca.at(std::get<0>(wire)).first.X(), Ca.at(std::get<0>(wire)).first.Y(), 0) ; + avgvec.second += std::get<1>(wire)*TVector3(Ca.at(std::get<0>(wire)).second.X(), Ca.at(std::get<0>(wire)).second.Y(), 0); + sumEnergy += std::get<1>(wire); + if(std::get<1>(wire) > maxEnergy) { + maxEnergy = std::get<1>(wire); + tsMaxEnergy = std::get<2>(wire); + } + } + avgvec.first = avgvec.first*(1.0/sumEnergy); + avgvec.second = avgvec.second*(1.0/sumEnergy); + double phi1 = avgvec.first.Phi(); + double phi2 = avgvec.second.Phi(); + avgvec.first.SetXYZ(radiusC*TMath::Cos(phi1), radiusC*TMath::Sin(phi1), -zLen/2); + avgvec.second.SetXYZ(radiusC*TMath::Cos(phi2), radiusC*TMath::Sin(phi2), zLen/2); + } + return std::tuple(avgvec, sumEnergy, maxEnergy, tsMaxEnergy); +} + +inline std::tuple PW::FindCrossoverProperties(const std::vector>& a_cluster, + const std::vector>& c_cluster) { + //std::pair apwire = GetPseudoWire(a_cluster,"ANODE",anodeSumE); + //std::pair cpwire = GetPseudoWire(c_cluster,"CATHODE",cathodeSumE); + auto [apwire, apSumE, apMaxE, apTSMaxE] = GetPseudoWire(a_cluster,"ANODE"); + auto [cpwire, cpSumE, cpMaxE, cpTSMaxE] = GetPseudoWire(c_cluster,"CATHODE"); + + TVector3 crossover; + crossover.Clear(); + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha=0; + + if(apSumE && cpSumE) { + a = apwire.first - apwire.second; + c = cpwire.first - cpwire.second; + diff = apwire.first - cpwire.first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + crossover = apwire.first + alpha*a; + if(crossover.z() < -190 || crossover.Z() > 190 ) { + alpha = 9999999; + apSumE=-1; cpSumE=-1; + apMaxE=-1; cpMaxE=-1; + apTSMaxE=-1; cpTSMaxE=-1; + } + } + //std::cout << apSumE << " " << cpSumE << " " << " " << crossover.Perp() << std::endl; + return std::tuple(crossover,alpha,apSumE,cpSumE,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE); +} + +inline void PW::FindWireID(TVector3 pos, TVector3 direction, bool verbose) +{ + + hitInfo.Clear(); + double phi = direction.Phi(); + + for (int i = 0; i < nWire; i++) + { + + double disA = 99999999; + double phiS = An[i].first.Phi() - TMath::PiOver4(); + double phiL = An[i].second.Phi() + TMath::PiOver4(); + // printf("A%2d: %f %f | %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg(), phi * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disA = Distance(pos, pos + direction, An[i].first, An[i].second); + if (disA < hitInfo.nearestDist.first) + { + hitInfo.nearestDist.first = disA; + hitInfo.nearestWire.first = i; + } + } + + double disC = 99999999; + phiS = Ca[i].second.Phi() - TMath::PiOver4(); + phiL = Ca[i].first.Phi() + TMath::PiOver4(); + // printf("C%2d: %f %f\n", i, phiS * TMath::RadToDeg(), phiL * TMath::RadToDeg()); + if (phi > 0 && phiS > phiL) + phiL = phiL + TMath::TwoPi(); + if (phi < 0 && phiS > phiL) + phiS = phiS - TMath::TwoPi(); + + if (phiS < phi && phi < phiL) + { + disC = Distance(pos, pos + direction, Ca[i].first, Ca[i].second); + if (disC < hitInfo.nearestDist.second) + { + hitInfo.nearestDist.second = disC; + hitInfo.nearestWire.second = i; + } + } + + if (verbose) + printf(" %2d | %8.2f, %8.2f\n", i, disA, disC); + } + + //==== find the 2nd nearest wire + short anode1 = hitInfo.nearestWire.first; + short aaa1 = anode1 - 1; + if (aaa1 < 0) + aaa1 += nWire; + short aaa2 = (anode1 + 1) % nWire; + + double haha1 = Distance(pos, pos + direction, An[aaa1].first, An[aaa1].second); + double haha2 = Distance(pos, pos + direction, An[aaa2].first, An[aaa2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.first = aaa1; + hitInfo.nextNearestDist.first = haha1; + } + else + { + hitInfo.nextNearestWire.first = aaa2; + hitInfo.nextNearestDist.first = haha2; + } + + short cathode1 = hitInfo.nearestWire.second; + short ccc1 = cathode1 - 1; + if (ccc1 < 0) + ccc1 += nWire; + short ccc2 = (cathode1 + 1) % nWire; + + haha1 = Distance(pos, pos + direction, Ca[ccc1].first, Ca[ccc1].second); + haha2 = Distance(pos, pos + direction, Ca[ccc2].first, Ca[ccc2].second); + if (haha1 < haha2) + { + hitInfo.nextNearestWire.second = ccc1; + hitInfo.nextNearestDist.second = haha1; + } + else + { + hitInfo.nextNearestWire.second = ccc2; + hitInfo.nextNearestDist.second = haha2; + } + + if (verbose) + Print(); +} + +inline void PW::CalTrack(TVector3 sx3Pos, int anodeID, int cathodeID, bool verbose) +{ + + trackPos = sx3Pos; + + TVector3 n1 = (An[anodeID].first - An[anodeID].second).Cross((sx3Pos - An[anodeID].second)).Unit(); + TVector3 n2 = (Ca[cathodeID].first - Ca[cathodeID].second).Cross((sx3Pos - Ca[cathodeID].second)).Unit(); + + // if the handiness of anode and cathode revered, it should be n2 cross n1 + trackVec = (n2.Cross(n1)).Unit(); + + if (verbose) + printf("Theta, Phi = %f, %f \n", trackVec.Theta() * TMath::RadToDeg(), trackVec.Phi() * TMath::RadToDeg()); +} + + +inline void PW::CalTrack2(TVector3 siPos, TVector3 anodeInt, bool verbose) +{ + + double mx, my; + double z; + mx = siPos.X() / (siPos.X() - anodeInt.X()); + my = siPos.Y() / (siPos.Y() - anodeInt.Y()); + z=siPos.Z() + mx * (anodeInt.Z() - siPos.Z()); + // if (mx == my) + { + trackVec=TVector3(0,0,z); + } + + if (verbose) + printf("X slope = %f and Y slope = %f \n", mx, my); +} + +/*inline TVector3 PW::CalTrack3(TVector3 siPos, TVector3 anodeInt, bool verbose) +{ + + TVector3 v = anodeInt-siPos; + double t_minimum = -1.0*(siPos.X()*v.X()+siPos.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 vector_closest_to_z = siPos + t_minimum*v; + + return vector_closest_to_z; + if (verbose) + printf("X slope = %f and Y slope = %f \n", mx, my); +}*/ + +inline double PW::GetZ0() +{ + + double x = trackPos.X(); + double y = trackPos.Y(); + double rho = TMath::Sqrt(x * x + y * y); + double theta = trackVec.Theta(); + + return trackVec.Z(); +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/ClassSX3.h b/anasen_analysis_vignesh/Armory/ClassSX3.h new file mode 100644 index 0000000..3586292 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassSX3.h @@ -0,0 +1,257 @@ +#ifndef ClassSX3_h +#define ClassSX3_h + +#include +#include +#include +#include + +class SX3{ +public: + SX3(){Clear();}; + ~SX3(){} + + short GetID() const {return id;} + short GetChUp() const {return chUp;} + short GetChDn() const {return chDn;} + short GetChBk() const {return chBk;} + + TVector3 GetHitPos() const {return hitPos;} + TVector3 GetHitPosWithSigma(double sigmaY_mm, double sigmaZ_mm); + + double GetZFrac() const {return zFrac;} // range from -0.5 to 0.5 + + void Clear(); + void ConstructGeo(); + void FindSX3Pos(TVector3 pos, TVector3 direction, bool verbose = false); + void CalSX3Pos(unsigned short ID, unsigned short chUp, unsigned short chDown, unsigned short chBack, float eUp, float eDown); + + double GetNumDet() const {return numDet;} + double GetWidth() const {return width;} + double GetLength() const {return length;} + TVector3 GetDnL(short id) const {return SDn[id].first; } // lower strip ID + TVector3 GetDnH(short id) const {return SDn[id].second; } // higher strip ID + TVector3 GetUpL(short id) const {return SUp[id].first; } // lower strip ID + TVector3 GetUpH(short id) const {return SUp[id].second; } // higher strip ID + + TVector3 GetDnMid(short id) const { return (SDn[id].first + SDn[id].second)*0.5;} + TVector3 GetUpMid(short id) const { return (SUp[id].first + SUp[id].second)*0.5;} + + double GetDetPhi(short id) const { return (SUp[id].second - SUp[id].first).Phi();} + + void Print(){ + if( id == -1 ){ + printf("Did not hit any SX3.\n"); + }else{ + printf("ID: %d, U,D,B: %d %d %d| zFrac : %.2f\n", id, chUp, chDn, chBk, zFrac); + printf("Hit Pos: %.2f, %.2f, %.2f\n", hitPos.X(), hitPos.Y(), hitPos.Z()); + } + } + + // void CalZFrac(){ + // zFrac = (eUp - eDn)/(eUp + eDn); + // } + +private: + + const int numDet = 12; + const float radius = 88; + const float width = 40; + const float length = 75; + const float gap = 46; + + short id; // -1 when no hit + short chUp; + short chDn; + short chBk; + + double zFrac; // from +1 (downstream) to -1 (upstream) + + double eUp; + double eDn; + double eBk; + + TVector3 hitPos; + + std::vector> SDn; // coners of the SX3 0-11, z = mid point + std::vector> SUp; // coners of the SX3 12-23, z = mid point + std::vector SNorml; // normal of the SX3 (outward) + + + std::pair Intersect(TVector3 p1, TVector3 p2, TVector3 q1, TVector3 q2, bool verbose){ + + //see https://nukephysik101.wordpress.com/2023/12/30/intersect-between-2-line-segments/ + //zero all z-component + TVector3 a0 = p1; a0.SetZ(0); + TVector3 a1 = p2; a1.SetZ(0); + + TVector3 b0 = q1; b0.SetZ(0); + TVector3 b1 = q2; b1.SetZ(0); + + double A = ((b0-b1).Cross(a0-a1)).Mag(); + + double h = ((b0-a0).Cross(b1-a0)).Z()/ A; + double k = ((a1-b0).Cross(a0-b0)).Z()/ A; + + if( verbose ) printf(" ----h, k : %f, %f\n", h, k); + + return std::pair(h,k); + } + +}; + +inline void SX3::Clear(){ + id = -1; + chUp = -1; + chDn = -1; + chBk = -1; + zFrac = TMath::QuietNaN(); + + eUp = TMath::QuietNaN(); + eDn = TMath::QuietNaN(); + eBk = TMath::QuietNaN(); + + SDn.clear(); + SUp.clear(); +} + +inline void SX3::ConstructGeo(){ + TVector3 sa, sb, sc, sn; + + for(int i = 0; i < numDet; i++){ + sa.SetXYZ( radius, -width/2, gap/2 + length/2 ); + sb.SetXYZ( radius, width/2, gap/2 + length/2 ); + + double rot = TMath::TwoPi() / numDet * (i - 0.5) - TMath::PiOver2(); + + sa.RotateZ( rot ); + sb.RotateZ( rot ); + SDn.push_back(std::pair(sa,sb)); + + sc.SetXYZ( radius, -width/2, gap/2 ); + sc.RotateZ( rot ); + + sn = ((sc-sa).Cross(sb-sa)).Unit(); + SNorml.push_back(sn); + + sa.SetXYZ( radius, -width/2, -gap/2 - length/2 ); + sb.SetXYZ( radius, width/2, -gap/2 - length/2 ); + + sa.RotateZ( rot ); + sb.RotateZ( rot ); + SUp.push_back(std::pair(sa,sb)); + } +} + + +inline void SX3::FindSX3Pos(TVector3 pos, TVector3 direction, bool verbose){ + + id = -1; + for( int i = 0 ; i < numDet; i++){ + + if(verbose) printf(" %d ", i); + std::pair frac = Intersect( pos, pos + direction, SDn[i].first, SDn[i].second, verbose); + + + if( frac.second < 0 || frac.second > 1 ) continue; + hitPos = pos + frac.first * direction; + + double dis = hitPos.Dot(SNorml[i]); + + if(verbose) { + printf("reduced distance : %f\n", dis); + printf(" %d*", (i+1)%numDet); + Intersect( pos, pos + direction, SDn[(i+1)%numDet].first, SDn[(i+1)%numDet].second, verbose); + } + + if( TMath::Abs(dis - radius) > 0.1 ) continue; + + chDn = 2 * TMath::Floor(frac.second * 4); + chUp = chDn + 1; + + double zPos = hitPos.Z(); + if( (gap/2 < zPos && zPos < gap/2 + length ) || (-gap/2 - length < zPos && zPos < -gap/2 ) ){ + + id = zPos > 0 ? i : i + 12; + + zFrac = zPos > 0 ? (zPos - gap/2. - length/2.)/length : (zPos - ( - gap/2. - length/2.) )/length ; + + chBk = TMath::Floor( (zFrac + 0.5) * 4 ) + 8; + + if( verbose) Print(); + return ; + + }else{ + if( verbose ) printf(" zPos out of sensitive region\n"); + } + } + + if( verbose) Print(); +} + +inline TVector3 SX3::GetHitPosWithSigma(double sigmaY_mm, double sigmaZ_mm){ + + double phi = SNorml[id%numDet].Phi(); + + TVector3 haha = hitPos; + haha.RotateZ(-phi); + + double y = haha.Y() + gRandom->Gaus(0, sigmaY_mm); + if( sigmaY_mm < 0 ){ + double deltaW = width/4; + y = TMath::Floor((haha.Y()-deltaW)/deltaW)*deltaW + deltaW*1.5; // when ever land on each strip, set the position to be center of the strip. + if( y >= 25 ) y = 15; + } + + double z = haha.Z() + gRandom->Gaus(0, sigmaZ_mm); + if( sigmaZ_mm < 0 ){ + haha.Z(); + double delta = length/4; + int sign = z > 0 ? 1 : -1; + z = TMath::Floor( (abs(z)-gap/2)/delta )*delta + 0.5 * delta + gap/2; + if( z >= 107.375 ) z = 88.625; + z = sign * z; + } + + haha.SetY(y); + haha.SetZ(z); + haha.RotateZ(phi); + + return haha; + +} + + +inline void SX3::CalSX3Pos(unsigned short ID, unsigned short chUp, unsigned short chDown, unsigned short chBack, float eUp, float eDown){ + + hitPos.Clear(); + + + if( (chUp - chDown) != 1 || (chDown % 2) != 0) return ; + + int reducedID = ID % numDet; + + TVector3 sa, sb; + + if( ID < numDet ){ //down + sa = SDn[reducedID].second; + sb = SDn[reducedID].first; + }else{ + sa = SUp[reducedID].second; + sb = SUp[reducedID].first; + } + + hitPos.SetX( (sb.X() - sa.X()) * chUp/8 + sa.X()); + hitPos.SetY( (sb.Y() - sa.Y()) * chUp/8 + sa.Y()); + + if( eUp == 0 || eDown == 0 ){ + hitPos.SetZ( sa.Z() + (2*(chBk - 7)-1) * length / 8 ); + }else{ + double frac = (eUp - eDown)/(eUp + eDown); // from +1 (downstream) to -1 (upstream) + double zPos = sa.Z() + length * frac/2; + hitPos.SetZ( zPos ); + } + +} + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/ClassTransfer.h b/anasen_analysis_vignesh/Armory/ClassTransfer.h new file mode 100644 index 0000000..c12c43f --- /dev/null +++ b/anasen_analysis_vignesh/Armory/ClassTransfer.h @@ -0,0 +1,468 @@ +#ifndef ClassTransfer_h +#define ClassTransfer_h + +#include "TBenchmark.h" +#include "TLorentzVector.h" +#include "TVector3.h" +#include "TMath.h" +#include "TFile.h" +#include "TTree.h" +#include "TRandom.h" +#include "TMacro.h" +#include "TGraph.h" +#include +#include + +#include "Isotope.h" + +class ReactionConfig{ + +public: + + ReactionConfig(){} + ~ReactionConfig(){} + + int beamA, beamZ; + int targetA, targetZ; + int recoilLightA, recoilLightZ; + int recoilHeavyA, recoilHeavyZ; + + float beamEnergy; ///MeV/u + float beamEnergySigma; ///beam-energy_sigma_in_MeV/u + float beamAngle; ///beam-angle_in_mrad + float beamAngleSigma; ///beam-emittance_in_mrad + float beamX; ///x_offset_of_Beam_in_mm + float beamY; ///y_offset_of_Beam_in_mm + int numEvents; ///number_of_Event_being_generated + bool isTargetScattering; ///isTargetScattering + float targetDensity; ///target_density_in_g/cm3 + float targetThickness; ///targetThickness_in_cm + std::string beamStoppingPowerFile; ///stopping_power_for_beam + std::string recoilLightStoppingPowerFile; ///stopping_power_for_light_recoil + std::string recoilHeavyStoppingPowerFile; ///stopping_power_for_heavy_recoil + bool isDecay; ///isDacay + int heavyDecayA; ///decayNucleus_A + int heavyDecayZ; ///decayNucleus_Z + bool isRedo; ///isReDo + std::vector beamEx; ///excitation_energy_of_A[MeV] + + + void SetReaction(int beamA, int beamZ, + int targetA, int targetZ, + int recoilA, int recoilZ, float beamEnergy_AMeV){ + this->beamA = beamA; + this->beamZ = beamZ; + this->targetA = targetA; + this->targetZ = targetZ; + this->recoilLightA = recoilA; + this->recoilLightZ = recoilZ; + + recoilHeavyA = this->beamA + this->targetA - recoilLightA; + recoilHeavyZ = this->beamZ + this->targetZ - recoilLightZ; + + } + + void LoadReactionConfig(TMacro * macro){ + + if( macro == NULL ) return ; + + int numLine = macro->GetListOfLines()->GetSize(); + + for( int i = 0; i < numLine; i ++){ + + std::vector str = SplitStr(macro->GetListOfLines()->At(i)->GetName(), " "); + + ///printf("%d | %s\n", i, str[0].c_str()); + + if( str[0].find_first_of("#") == 0 ) break; + + if( i == 0 ) beamA = atoi(str[0].c_str()); + if( i == 1 ) beamZ = atoi(str[0].c_str()); + if( i == 2 ) targetA = atoi(str[0].c_str()); + if( i == 3 ) targetZ = atoi(str[0].c_str()); + if( i == 4 ) recoilLightA = atoi(str[0].c_str()); + if( i == 5 ) recoilLightZ = atoi(str[0].c_str()); + if( i == 6 ) beamEnergy = atof(str[0].c_str()); + if( i == 7 ) beamEnergySigma = atof(str[0].c_str()); + if( i == 8 ) beamAngle = atof(str[0].c_str()); + if( i == 9 ) beamAngleSigma = atof(str[0].c_str()); + if( i == 10 ) beamX = atof(str[0].c_str()); + if( i == 11 ) beamY = atof(str[0].c_str()); + if( i == 12 ) numEvents = atoi(str[0].c_str()); + if( i == 13 ) { + if( str[0].compare("false") == 0 ) isTargetScattering = false; + if( str[0].compare("true") == 0 ) isTargetScattering = true; + } + if( i == 14 ) targetDensity = atof(str[0].c_str()); + if( i == 15 ) targetThickness = atof(str[0].c_str()); + if( i == 16 ) beamStoppingPowerFile = str[0]; + if( i == 17 ) recoilLightStoppingPowerFile = str[0]; + if( i == 18 ) recoilHeavyStoppingPowerFile = str[0]; + if( i == 19 ) { + if( str[0].compare("false") == 0 ) isDecay = false; + if( str[0].compare("true") == 0 ) isDecay = true; + } + if( i == 20 ) heavyDecayA = atoi(str[0].c_str()); + if( i == 21 ) heavyDecayZ = atoi(str[0].c_str()); + if( i == 22 ) { + if( str[0].compare("false") == 0 ) isRedo = false; + if( str[0].compare("true" ) == 0 ) isRedo = true; + } + + if( i >= 23) { + beamEx.push_back( atof(str[0].c_str()) ); + } + } + + recoilHeavyA = beamA + targetA - recoilLightA; + recoilHeavyZ = beamZ + targetZ - recoilLightZ; + + } + + void PrintReactionConfig(){ + + printf("=====================================================\n"); + printf(" beam : A = %3d, Z = %2d \n", beamA, beamZ); + printf(" target : A = %3d, Z = %2d \n", targetA, targetZ); + printf(" light : A = %3d, Z = %2d \n", recoilLightA, recoilLightZ); + + printf(" beam Energy : %.2f +- %.2f MeV/u, dE/E = %5.2f %%\n", beamEnergy, beamEnergySigma, beamEnergySigma/beamEnergy); + printf(" Angle : %.2f +- %.2f mrad\n", beamAngle, beamAngleSigma); + printf(" offset : (x,y) = (%.2f, %.2f) mmm \n", beamX, beamY); + + printf("##### number of Simulation Events : %d \n", numEvents); + + printf(" is target scattering : %s \n", isTargetScattering ? "Yes" : "No"); + + if(isTargetScattering){ + printf(" target density : %.f g/cm3\n", targetDensity); + printf(" thickness : %.f cm\n", targetThickness); + printf(" beam stopping file : %s \n", beamStoppingPowerFile.c_str()); + printf(" recoil light stopping file : %s \n", recoilLightStoppingPowerFile.c_str()); + printf(" recoil heavy stopping file : %s \n", recoilHeavyStoppingPowerFile.c_str()); + } + + printf(" is simulate decay : %s \n", isDecay ? "Yes" : "No"); + if( isDecay ){ + printf(" heavy decay : A = %d, Z = %d \n", heavyDecayA, heavyDecayZ); + } + printf(" is Redo until hit array : %s \n", isRedo ? "Yes" : "No"); + + printf(" beam Ex : %.2f MeV \n", beamEx[0]); + for( int i = 1; i < (int) beamEx.size(); i++){ + printf(" %.2f MeV \n", beamEx[i]); + } + + printf("=====================================================\n"); + + } + +}; + +//======================================================= +//####################################################### +// Class for Transfer Reaction +// reaction notation A(a,b)B +// A = incident particle +// a = target +// b = light scattered particle +// B = heavy scattered particle +//======================================================= +class TransferReaction { +public: + TransferReaction(); + ~TransferReaction(); + + void SetA(int A, int Z, double Ex); + void Seta(int A, int Z); + void Setb(int A, int Z); + void SetB(int A, int Z); + void SetIncidentEnergyAngle(double KEA, double theta, double phi); + void SetExA(double Ex); + void SetExB(double Ex); + void SetReactionFromFile(string settingFile); + + TString GetReactionName(); + TString GetReactionName_Latex(); + + ReactionConfig GetRectionConfig() { return reaction;} + + double GetMass_A(){return mA + ExA;} + double GetMass_a(){return ma;} + double GetMass_b(){return mb;} + double GetMass_B(){return mB + ExB;} + + double GetCMTotalKE() {return Etot - mA - ma;} + double GetQValue() {return mA + ExA + ma - mb - mB - ExB;} + double GetMaxExB() {return Etot - mb - mB;} + + TLorentzVector GetPA(){return PA;} + TLorentzVector GetPa(){return Pa;} + TLorentzVector GetPb(){return Pb;} + TLorentzVector GetPB(){return PB;} + + void CalReactionConstant(); + + TLorentzVector * Event(double thetaCM, double phiCM); + + double GetEx(){return Ex;} + double GetThetaCM(){return thetaCM;} + + double GetMomentumbCM() {return p;} + double GetReactionBeta() {return beta;} + double GetReactionGamma() {return gamma;} + double GetCMTotalEnergy() {return Etot;} + +private: + + ReactionConfig reaction; + + string nameA, namea, nameb, nameB; + double thetaIN, phiIN; + double mA, ma, mb, mB; + + double TA, T; // TA = KE of A pre u, T = total energy + double ExA, ExB; + double Ex, thetaCM; //calculated Ex using inverse mapping from e and z to thetaCM + + bool isReady; + bool isBSet; + + double k; // CM Boost momentum + double beta, gamma; //CM boost beta + double Etot; + double p; // CM frame momentum of b, B + + TLorentzVector PA, Pa, Pb, PB; + + TString format(TString name); + +}; + +TransferReaction::TransferReaction(){ + + thetaIN = 0.; + phiIN = 0.; + SetA(24, 12, 0); + Seta(4,2); + Setb(1,1); + SetB(27,13); + TA = 2.5; + T = TA * reaction.beamA; + + ExA = 0; + ExB = 0; + + Ex = TMath::QuietNaN(); + thetaCM = TMath::QuietNaN(); + + CalReactionConstant(); + + TLorentzVector temp (0,0,0,0); + PA = temp; + Pa = temp; + Pb = temp; + PB = temp; + +} + +TransferReaction::~TransferReaction(){ + +} + +void TransferReaction::SetA(int A, int Z, double Ex = 0){ + Isotope temp (A, Z); + mA = temp.Mass; + reaction.beamA = A; + reaction.beamZ = Z; + ExA = Ex; + nameA = temp.Name; + isReady = false; + isBSet = true; + +} + +void TransferReaction::Seta(int A, int Z){ + Isotope temp (A, Z); + ma = temp.Mass; + reaction.targetA = A; + reaction.targetZ = Z; + namea = temp.Name; + isReady = false; + isBSet = false; +} + +void TransferReaction::Setb(int A, int Z){ + Isotope temp (A, Z); + mb = temp.Mass; + reaction.recoilLightA = A; + reaction.recoilLightZ = Z; + nameb = temp.Name; + isReady = false; + isBSet = false; +} +void TransferReaction::SetB(int A, int Z){ + Isotope temp (A, Z); + mB = temp.Mass; + reaction.recoilHeavyA = A; + reaction.recoilHeavyZ = Z; + nameB = temp.Name; + isReady = false; + isBSet = true; +} + +void TransferReaction::SetIncidentEnergyAngle(double KEA, double theta, double phi){ + this->TA = KEA; + this->T = TA * reaction.beamA; + this->thetaIN = theta; + this->phiIN = phi; + isReady = false; +} + +void TransferReaction::SetExA(double Ex){ + this->ExA = Ex; + isReady = false; +} + +void TransferReaction::SetExB(double Ex){ + this->ExB = Ex; + isReady = false; +} + +void TransferReaction::SetReactionFromFile(string settingFile){ + + TMacro * haha = new TMacro(); + if( haha->ReadFile(settingFile.c_str()) > 0 ) { + reaction.LoadReactionConfig(haha); + + SetA(reaction.beamA, reaction.beamZ); + Seta(reaction.targetA, reaction.targetZ); + Setb(reaction.recoilLightA, reaction.recoilLightZ); + SetB(reaction.recoilHeavyA, reaction.recoilHeavyZ); + + SetIncidentEnergyAngle(reaction.beamEnergy, 0, 0); + CalReactionConstant(); + }else{ + + printf("cannot read file %s.\n", settingFile.c_str()); + isReady = false; + } + +} + +TString TransferReaction::GetReactionName(){ + TString rName; + rName.Form("%s(%s,%s)%s", nameA.c_str(), namea.c_str(), nameb.c_str(), nameB.c_str()); + return rName; +} + +TString TransferReaction::format(TString name){ + if( name.IsAlpha() ) return name; + int len = name.Length(); + TString temp = name; + TString temp2 = name; + if( temp.Remove(0, len-2).IsAlpha()){ + temp2.Remove(len-2); + }else{ + temp = name; + temp.Remove(0, len-1); + temp2.Remove(len-1); + } + return "^{"+temp2+"}"+temp; +} + +TString TransferReaction::GetReactionName_Latex(){ + TString rName; + rName.Form("%s(%s,%s)%s", format(nameA).Data(), format(namea).Data(), format(nameb).Data(), format(nameB).Data()); + return rName; +} + +void TransferReaction::CalReactionConstant(){ + if( !isBSet){ + reaction.recoilHeavyA = reaction.beamA + reaction.targetA - reaction.recoilLightA; + reaction.recoilHeavyZ = reaction.beamZ + reaction.targetZ - reaction.recoilLightZ; + Isotope temp (reaction.recoilHeavyA, reaction.recoilHeavyZ); + mB = temp.Mass; + isBSet = true; + } + + k = TMath::Sqrt(TMath::Power(mA + ExA + T, 2) - (mA + ExA) * (mA + ExA)); + beta = k / (mA + ExA + ma + T); + gamma = 1 / TMath::Sqrt(1- beta * beta); + Etot = TMath::Sqrt(TMath::Power(mA + ExA + ma + T,2) - k * k); + p = TMath::Sqrt( (Etot*Etot - TMath::Power(mb + mB + ExB,2)) * (Etot*Etot - TMath::Power(mb - mB - ExB,2)) ) / 2 / Etot; + + PA.SetXYZM(0, 0, k, mA + ExA); + PA.RotateY(thetaIN); + PA.RotateZ(phiIN); + + Pa.SetXYZM(0,0,0,ma); + + isReady = true; +} + +TLorentzVector * TransferReaction::Event(double thetaCM, double phiCM) +{ + if( isReady == false ){ + CalReactionConstant(); + } + + //TLorentzVector Pa(0, 0, 0, ma); + + //---- to CM frame + TLorentzVector Pc = PA + Pa; + TVector3 b = Pc.BoostVector(); + + TVector3 vb(0,0,0); + + if( b.Mag() > 0 ){ + TVector3 v0 (0,0,0); + TVector3 nb = v0 - b; + + TLorentzVector PAc = PA; + PAc.Boost(nb); + TVector3 vA = PAc.Vect(); + + TLorentzVector Pac = Pa; + Pac.Boost(nb); + TVector3 va = Pac.Vect(); + + //--- construct vb + vb = va; + vb.SetMag(p); + + TVector3 ub = vb.Orthogonal(); + vb.Rotate(thetaCM, ub); + vb.Rotate(phiCM + TMath::PiOver2(), va); // somehow, the calculation turn the vector 90 degree. + //vb.Rotate(phiCM , va); // somehow, the calculation turn the vector 90 degree. + } + + //--- from Pb + TLorentzVector Pbc; + Pbc.SetVectM(vb, mb); + + //--- from PB + TLorentzVector PBc; + //PBc.SetVectM(vB, mB + ExB); + PBc.SetVectM(-vb, mB + ExB); + + //---- to Lab Frame + TLorentzVector Pb = Pbc; + Pb.Boost(b); + TLorentzVector PB = PBc; + PB.Boost(b); + + TLorentzVector * output = new TLorentzVector[4]; + output[0] = PA; + output[1] = Pa; + output[2] = Pb; + output[3] = PB; + + this->Pb = Pb; + this->PB = PB; + + + return output; +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/HistPlotter.h b/anasen_analysis_vignesh/Armory/HistPlotter.h new file mode 100644 index 0000000..a0e21dc --- /dev/null +++ b/anasen_analysis_vignesh/Armory/HistPlotter.h @@ -0,0 +1,416 @@ +#ifndef HISTPLOTTER_H +#define HISTPLOTTER_H +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +class HistPlotter { +private: + long long barrier_count, barrier_limit; //meant to keep track of how often to call FillN() on histograms + enum {TFILE, TMEMFILE} filetype; + std::unordered_map oMap; //!< Maps std::string to all TH1, TH2 objects in the class + std::unordered_map cutsMap; //!< Maps std::string to TCutG objects held by the class + std::set folderList; //!< List of all folder names used to nest objects + std::unordered_map foldersForObjects; //!< Map that returns the folder corresponding to the object whose pointer is specified + TFile *ofile=nullptr; //!< TFile pointer for the output file + TMemFile *omfile=nullptr; //!< TFile pointer for the output memfile + + //Caches to permit FillN() calls + std::unordered_map> onedimcache; + std::unordered_map, std::vector>> twodimcache; + inline void FillN_All_Histograms(); +public: + HistPlotter(std::string outfile, std::string type); + inline void FlushToDisk(int integral); //!< Writes all objects to file before closing, nesting objects in folders as is found necessary + inline void PrintObjects(); //!< Dump objects to std::cout for inspection + inline void ReadCuts(std::string); + inline TCutG* FindCut(std::string cut) { + return static_cast(cutsMap.at(cut)); + } + inline void set_barrier_limit(long long limit) { barrier_limit = limit; } + inline void barrier_increment() { + barrier_count++; + if(barrier_count == barrier_limit) { + FillN_All_Histograms(); + barrier_count=0; + } + } + /*! \fn void FindCut() + \brief + - Searches for a cut by name 'cut' in the internal list of cuts 'cutsMap'. Ugly fails (via unresolved at()) if such a cut isn't found. + \param filename - name of the plainxtext file containing the cut file locations and identifiers + \return Pointer to the TCutG object that matches the name. Very useful to use this as plotter.FindCut("protonbarrelpid")->IsInside(deltaE, E) for instance. + */ + + inline void SetNewTitle(std::string name, std::string title) { + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) return; //no warnings, could be changed in future + else + static_cast(oMap.at(name))->SetTitle(title.c_str()); // set new title + } + + //Smart functions that create a new histogram if it doesn't exist. + inline void FillGraph(const std::string &name, float valuex, float valuey, float errx=0, float erry=0); + inline void Fill1D(const std::string& name,int nbinsx, float xlow, float xhigh, float value); + inline void Fill2D(const std::string& name,int nbinsx, float xlow, float xhigh + ,int nbinsy, float ylow, float yhigh, float valuex, float valuey); + inline void Fill1D(const std::string& name,int nbinsx, float xlow, float xhigh, float value, const std::string& folder); + inline void Fill2D(const std::string& name,int nbinsx, float xlow, float xhigh + ,int nbinsy, float ylow, float yhigh, float valuex, float valuey, const std::string& folder); + //TObject* findObject(std::string key); +}; + +HistPlotter::HistPlotter(std::string outfile, std::string type="") { + /*! + \brief Constructor. Opens a TFile instance with the specified filename + \param outfile : std::string that holds the desired output ROOT filename + \return None + */ + if(type=="" || type == "TFILE") { + ofile = new TFile(outfile.c_str(),"recreate"); + filetype = TFILE; + } else if(type =="TMEMFILE") { + omfile = new TMemFile(outfile.c_str(),"recreate"); + filetype=TMEMFILE; + } else { + std::cout << "Unknown type "<< type << " specified for HistPlotter (use \"TFILE\" or \"TMEMFILE\"), using default \"TFILE\" " << std::endl; + ofile = new TFile(outfile.c_str(),"recreate"); + filetype = TFILE; + } + barrier_count=0; + barrier_limit=1000; +} + +void HistPlotter::FillN_All_Histograms() { + for(auto it=oMap.begin(); it!=oMap.end(); it++ ) { + //it->first is std::string 'name', it->second is the TObject + if(it->second->InheritsFrom("TH1F")) { + //FillN(size, array-of-doubles, array-of-weights); //we set array-of-weights to (1,1,1,.. (size) + static_cast(it->second)->FillN(onedimcache[it->first].size(), //size + onedimcache[it->first].data(), //array + std::vector(onedimcache[it->first].size(),1.0).data()); //weight of ones + onedimcache[it->first].clear(); + } else if(it->second->InheritsFrom("TH2F")) { + //FillN(size, array-of-doubles, array-of-weights); //we set array-of-weights to (1,1,1,.. (size)) + static_cast(it->second)->FillN(twodimcache[it->first].first.size(), //size + twodimcache[it->first].first.data(), //x array + twodimcache[it->first].second.data(), //y array + std::vector(twodimcache[it->first].first.size(),1.0).data()); //weight of ones + twodimcache[it->first].first.clear(); + twodimcache[it->first].second.clear(); + } + } + std::cout << "." << std::endl; +} + +void HistPlotter::FlushToDisk(int min_integral=0) { + /*! \fn void FlushToDisk() + \brief Function that can be used at any point to exit smoothly by saving all ROOT objects in memory + to the output file before closing it. Obeys the binding of histograms to separate folders, if so specified. + \return No return -- void + */ + if(filetype==TMEMFILE && omfile) { + std::cout << "Not flushing a TMemfile .. exiting .." << std::endl; + delete omfile; + return; + } + if(ofile->IsZombie() || !ofile) { + std::cerr << "Output file is zombie, finishing up without writing to disk!" << std::endl; + return; + } + FillN_All_Histograms(); + for(auto it=oMap.begin(); it!=oMap.end(); it++ ) { + //omap maps: name(first) to object address(second). + // foldersForObjects maps: object address(first) to foldername(second) + auto result = foldersForObjects.find(it->second); //returns pair if found + if(result!=foldersForObjects.end()) { //we try to create folder if needed and cd to it + ofile->mkdir(result->second.c_str(),"",kTRUE); // args: name, title, returnExistingDirectory + ofile->cd(result->second.c_str()); + } else { + ofile->cd(); //toplevel for all default histograms. Default setting + } + if(((TH1F*)it->second)->Integral()>min_integral) + it->second->Write(); + } + + //Create a directory for all cuts, and save all cuts in them + ofile->mkdir("gCUTS","",kTRUE); + ofile->cd("gCUTS"); + for(auto it=cutsMap.begin(); it!=cutsMap.end(); it++) { + (static_cast(it->second))->SetName(it->first.c_str()); + it->second->Write(); + } + ofile->Close(); + std::cout << "Wrote " << oMap.size() << " histograms to TFile " << std::string(ofile->GetName()) << std::endl; +} + +void HistPlotter::FillGraph(const std::string& name, float valuex, float valuey, float errx, float erry) { + /*! \fn void FillGraph() + \brief + - Creates a TGraphError in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TGraph* + + \param name name of the TGraph + \param valuex The xvalue + \param valuey The yvalue + \param errx The x error + \param erry The y error + \return No return void + */ + auto result = oMap.find(name); + if(result==oMap.end()) { + TGraphErrors *tempG = new TGraphErrors(); + tempG->SetName(name.c_str()); + oMap.insert(std::make_pair(name,static_cast(tempG))); + } + if(!oMap.at(name)->InheritsFrom("TGraphErrors")) { + std::cerr << "Object " << name << " refers to something other than a TGraph*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + // static_cast(oMap.at(name))->AddPointError(valuex,valuey,errx,erry); +} + +void HistPlotter::Fill1D(const std::string& name, int nbinsx, float xlow, float xhigh, float value) { + /*! \fn void Fill1D() + \brief + - Creates a TH1F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH1* + + \param name name of the TH1F histogram + \param nbinsx Number of bins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param value The bin corresponding to value in (nbinsx, xlow, xhigh) is incremented by 1 + \return No return void + */ + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH1F* temp1D = new TH1F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh); + oMap.insert(std::make_pair(name,static_cast(temp1D))); + onedimcache.insert(std::make_pair(name, std::vector())); + onedimcache[name].reserve(16384); + } else if(foldersForObjects.find(oMap.at(name))!=foldersForObjects.end()) { //shouldn't have a folder associated with it + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in toplevel .." << std::endl; + } + + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH1F")) { + std::cerr << "Object " << name << " refers to something other than a TH1*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + onedimcache[name].emplace_back(value); + //static_cast(oMap.at(name))->Fill(value); +} + +void HistPlotter::Fill1D(const std::string& name, int nbinsx, float xlow, float xhigh, float value, const std::string& foldername) { + /*! \fn void Fill1D() + \brief + - Creates a TH1F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH1* + - Remembers the foldername this particular histogram maps to, if provided. If not, defaults to toplevel. + + \param name name of the TH1F histogram + \param nbinsx Number of bins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param value The bin corresponding to value in (nbinsx, xlow, xhigh) is incremented by 1 + \param foldername Name of the folder to put this histogram into. Defaults to toplevel if left empty + \return No return -- void + */ + + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH1F* temp1D = new TH1F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh); + oMap.insert(std::make_pair(name,static_cast(temp1D))); + onedimcache.insert(std::make_pair(name, std::vector())); + onedimcache[name].reserve(16384); + if(foldername!="") { + if(folderList.find(foldername)==folderList.end()) { + folderList.insert(foldername); + } + foldersForObjects.insert(std::make_pair(static_cast(temp1D),foldername)); + } + } else { + //object is present in map, but we enforce unique names + //it must already have a folder attached to it + if(foldersForObjects.find(oMap.at(name))==foldersForObjects.end()) { + std::cerr << "Object " << name << " already registered at toplevel, choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } else if(foldersForObjects[oMap[name]]!=foldername) { + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } + } + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH1F")) { + std::cerr << "Object " << name << " refers to something other than a TH1*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + onedimcache[name].emplace_back(value); + //static_cast(oMap.at(name))->Fill(value); +} + +void HistPlotter::Fill2D(const std::string& name, int nbinsx, float xlow, float xhigh, int nbinsy, float ylow, float yhigh, float valuex, float valuey) { + /*! \fn void Fill2D() + \brief + - Creates a TH2F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH2* + \param name name of the TH1F histogram + \param nbinsx Number of xbins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param nbinsy Number of ybins in the histogram + \param ylow Lower limit on y-axis + \param yhigh Upper limit on y-axis + \param valuex + \param valuey The bin corresponding to (valuex, valuey) in (nbinsx, xlow, xhigh, ybinsx, ylow, yhigh) is incremented by 1 + \return No return -- void + */ + + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH2F* temp2D = new TH2F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh, nbinsy, ylow, yhigh); + oMap.insert(std::make_pair(name,static_cast(temp2D))); + twodimcache.insert(std::make_pair(name, std::make_pair(std::vector(),std::vector()))); + twodimcache[name].first.reserve(16384); + twodimcache[name].second.reserve(16384); + } else if(foldersForObjects.find(oMap.at(name))!=foldersForObjects.end()) { //shouldn't have a folder associated with it + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in toplevel .." << std::endl; + } + + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH2F")) { + std::cerr << "Object " << name << " refers to something other than a TH2*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + twodimcache[name].first.emplace_back(valuex); + twodimcache[name].second.emplace_back(valuey); + //static_cast(oMap.at(name))->Fill(valuex,valuey); +} + +void HistPlotter::Fill2D(const std::string& name, int nbinsx, float xlow, float xhigh, int nbinsy, float ylow, float yhigh, float valuex, float valuey, const std::string& foldername) { + /*! \fn void Fill2D() + \brief + - Creates a TH2F in memory with name 'name' if it doesn't exist, and fills it with valuex, valuey + - Writes present state to disk and fails with return value -1 if the name clashes with another object that's not of type TH2* + - Remembers the foldername this particular histogram maps to, if provided. If not defaults to toplevel + + \param name name of the TH1F histogram + \param nbinsx Number of xbins in the histogram + \param xlow Lower limit on x-axis + \param xhigh Upper limit on x-axis + \param nbinsy Number of ybins in the histogram + \param ylow Lower limit on y-axis + \param yhigh Upper limit on y-axis + \param valuex + \param valuey The bin corresponding to (valuex, valuey) in (nbinsx, xlow, xhigh, ybinsx, ylow, yhigh) is incremented by 1 + \param foldername Name of the folder to put this histogram into. Defaults to toplevel if left empty + \return No return -- void + */ + + auto result = oMap.find(name); //result is an iterator + if(result==oMap.end()) { + TH2F* temp2D = new TH2F(name.c_str(), name.c_str(), nbinsx, xlow, xhigh, nbinsy, ylow, yhigh); + oMap.insert(std::make_pair(name,static_cast(temp2D))); + twodimcache.insert(std::make_pair(name, std::make_pair(std::vector(),std::vector()))); + twodimcache[name].first.reserve(16384); + twodimcache[name].second.reserve(16384); + if(foldername!="") { + if(folderList.find(foldername)==folderList.end()) { + folderList.insert(foldername); + } + foldersForObjects.insert(std::make_pair(static_cast(temp2D),foldername)); + } + } else { + //object is present in map, but we enforce unique names + //it must already have a folder attached to it + if(foldersForObjects.find(oMap.at(name))==foldersForObjects.end()) { + std::cerr << "Object " << name << " already registered at toplevel, choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } else if(foldersForObjects[oMap.at(name)]!=foldername) { + std::cerr << "Object " << name << " already registered at " << foldersForObjects[oMap[name]] << ", choose a different name for the histogram to be stored in " << foldername << " folder .." << std::endl; + } + } + + //Check if the string 'name' maps to a 1D hist. If there's any other object by this name raise issue + if(!oMap.at(name)->InheritsFrom("TH2F")) { + std::cerr << "Object " << name << " refers to something other than a TH2*, not filling it hence!" << std::endl; + std::cerr << "Abort.." << std::endl; + FlushToDisk(); + exit(-1); + } + twodimcache[name].first.emplace_back(valuex); + twodimcache[name].second.emplace_back(valuey); + //static_cast(oMap.at(name))->Fill(valuex,valuey); +} + +void HistPlotter::ReadCuts(std::string filename) { + /*! \fn void ReadCuts() + \brief Reads a list of cuts from a file. The file must have the format below, two columns + - Column#1 - path to a file that contains a single TCutG object named "CUTG", the default name in ROOT. + - Column#2 - The identifier name you plan to use in the code, like 'protonbarrelpid' or something, that will be searched by FindCut() + \param filename name of the plainxtext file containing the cut file locations and identifiers + \return No return -- void + */ + + std::ifstream infile; + infile.open(filename); + std::string cutfilename, cutname; + for(std::string line; std::getline(infile, line); ) { + if(line.size()!=0 && line[0]=='#') + ; //don't do anything with '#' lines + else { + std::stringstream ss(line); + ss>>cutfilename>>cutname; + + TFile f(cutfilename.c_str()); + if(f.IsZombie()) { + std::cerr << "Cannot open cutfile " << cutfilename << " .. skipping.." << std::endl; + continue; + } + TCutG *cut = (TCutG*)(f.Get("CUTG")); + cutsMap.insert(std::make_pair(cutname,static_cast(cut))); + f.Close(); + } //else + }//for loop + infile.close(); +} + +void HistPlotter::PrintObjects() { + /* + void PrintObjects() + Prints the contents of the unordered_maps oMap and cutsMap to facilitate debugging + + */ + std::cout << "Type | Name " << std::endl; + std::cout << "---- | --------------------- " << std::endl; + for(auto it=oMap.begin(); it!=oMap.end(); it++ ) { + std::cout << it->second->ClassName() << " | "<< it->first << std::endl; + } + for(auto it=cutsMap.begin(); it!=cutsMap.end(); it++ ) { + std::cout << it->second->ClassName() << " | "<< it->first << std::endl; + } + std::cout << "---- | --------------------- " << std::endl; +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/Isotope.h b/anasen_analysis_vignesh/Armory/Isotope.h new file mode 100644 index 0000000..d44cdc9 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Isotope.h @@ -0,0 +1,522 @@ +/*********************************************************************** + * + * This is Isotope.h, To extract the isotope mass from massXX.txt + * + *------------------------------------------------------- + * created by Ryan (Tsz Leung) Tang, Nov-18, 2018 + * email: goluckyryan@gmail.com + * ********************************************************************/ + + +#ifndef ISOTOPE_H +#define ISOTOPE_H + +#include +#include +#include +#include +#include +#include +#include "constant.h" // amu +#include //atoi +#include +using namespace std; + +string massData="mass20.txt"; + +// about the mass**.txt +// Mass Excess = (ATOMIC MASS - A)*amu | e.g. n : (1.088664.91585E-6-1)*amu +// mass excess uncertaintly +// BEA = (Z*M(1H) + N*M(1n) - Me(A,Z))/A , Me is the mass with electrons +// BEA = (Z*mp + N*mn - M(A,Z))/A , M is the mass without electrons + +class Isotope { +public: + int A, Z; + double Mass, MassError, BEA; + string Name, Symbol; + string dataSource; + + Isotope(){ dataSource = massData; }; + Isotope(int a, int z){ dataSource = massData; SetIso(a,z); }; + Isotope(string name){ dataSource = massData; SetIsoByName(name); }; + + void SetIso(int a, int z); + void SetIsoByName(string name); + + double CalSp(int Np, int Nn); // this for the Np-proton, Nn-neutron removal + double CalSp2(int a, int z); // this is for (a,z) nucleus removal + + double CalBeta(double T){ + // double Etot = Mass + T; + double gamma = 1 + T/Mass; + double beta = sqrt(1 - 1 / gamma / gamma ) ; + return beta; + } + + void Print(); + void ListShell(); + +private: + void FindMassByAZ(int a, int z); // give mass, massError, BEA, Name, Symbol; + void FindMassByName(string name); // give Z, mass, massError, BEA; + + int TwoJ(int nShell); + string Orbital(int nShell); + int magic(int i){ + switch (i){ + case 0: return 2; break; + case 1: return 8; break; + case 2: return 20; break; + case 3: return 28; break; + case 4: return 40; break; + case 5: return 50; break; + case 6: return 82; break; + case 7: return 128; break; + } + return 0; + } + + int magicShellID(int i){ + switch (i){ + case 0: return 0; break; + case 1: return 2; break; + case 2: return 5; break; + case 3: return 6; break; + case 4: return 9; break; + case 5: return 10; break; + case 6: return 15; break; + case 7: return 21; break; + } + return 0; + } + + int fileStartLine; + int fileEndLine; + int lineMass050_099; + int lineMass100_149; + int lineMass150_199; + int lineMass200; + + + void setFileLines(){ + fileStartLine = 37; + fileEndLine = 3594; + + lineMass050_099 = 466; + lineMass100_149 = 1160; + lineMass150_199 = 1994; + lineMass200 = 2774; + } + + char * heliosPath; + bool isFindOnce; + + +}; + +inline void Isotope::SetIso(int a, int z){ + this->A = a; + this->Z = z; + FindMassByAZ(a,z); +} + +inline void Isotope::SetIsoByName(string name){ + FindMassByName(name); +} + +inline void Isotope::FindMassByAZ(int A, int Z){ + string line; + int lineNum=0; + int list_A, list_Z; + + ifstream myfile; + int flag=0; + + setFileLines(); + + int numLineStart = fileStartLine; + int numLineEnd = fileEndLine; + + if ( A >= 50 && A < 100) numLineStart = lineMass050_099; + if ( A >=100 && A < 150) numLineStart = lineMass100_149; + if ( A >=150 && A < 200) numLineStart = lineMass150_199; + if ( A >=200 ) numLineStart = lineMass200; + + myfile.open(dataSource.c_str()); + + if (myfile.is_open()) { + while (/*! myfile.eof() &&*/ flag == 0 && lineNum = numLineStart ){ + list_Z = atoi((line.substr(10,5)).c_str()); + list_A = atoi((line.substr(15,5)).c_str()); + + if ( A == list_A && Z == list_Z) { + this->BEA = atof((line.substr(54,11)).c_str()); + this->Mass = list_Z*mp + (list_A-list_Z)*mn - this->BEA/1000*list_A; + this->MassError = atof((line.substr(65,7)).c_str()); + string str = line.substr(20,2); + str.erase(remove(str.begin(), str.end(), ' '), str.end()); + this->Symbol = str; + + ostringstream ss; + ss << A << this->Symbol; + this->Name = ss.str(); + flag = 1; + }else if ( list_A > A) { + this->BEA = -404; + this->Mass = -404; + this->MassError = -404; + this->Symbol = "non"; + this->Name = "non"; + break; + } + + } + } + + if( this->Name == "1H" ) this->Name = "p"; + if( this->Name == "2H" ) this->Name = "d"; + if( this->Name == "3H" ) this->Name = "t"; + if( this->Name == "4He" ) this->Name = "a"; + + myfile.close(); + }else { + printf("Unable to open %s\n", dataSource.c_str()); + } +} + +inline void Isotope::FindMassByName(string name){ + + // done seperate the Mass number and the name + if( name == "n" ) { + this->Name = "1n"; + this->BEA = 0; + this->Mass = mn; + this->MassError = 0; + this->Name = "n"; + this->A = 1; + this->Z = 0; + return; + } + if( name == "p" ) name = "1H"; + if( name == "d" ) name = "2H"; + if( name == "t" ) name = "3H"; + if( name == "a" ) name = "4He"; + + string temp = name; + int lastDigit = 0; + + for(int i=0; temp[i]; i++){ + if(temp[i] == '0') lastDigit = i; + if(temp[i] == '1') lastDigit = i; + if(temp[i] == '2') lastDigit = i; + if(temp[i] == '3') lastDigit = i; + if(temp[i] == '4') lastDigit = i; + if(temp[i] == '5') lastDigit = i; + if(temp[i] == '6') lastDigit = i; + if(temp[i] == '7') lastDigit = i; + if(temp[i] == '8') lastDigit = i; + if(temp[i] == '9') lastDigit = i; + } + + this->Symbol = temp.erase(0, lastDigit +1); + //check is Symbol is 2 charaters, if not, add " " at the end + if( this->Symbol.length() == 1 ){ + this->Symbol = this->Symbol + " "; + } + + + temp = name; + int len = temp.length(); + temp = temp.erase(lastDigit+1, len); + + this->A = atoi(temp.c_str()); + //printf(" Symbol = |%s| , Mass = %d\n", this->Symbol.c_str(), this->A); + + // find the nucleus in the data + string line; + int lineNum=0; + int list_A; + string list_symbol; + + ifstream myfile; + int flag=0; + + setFileLines(); + + int numLineStart = fileStartLine; + int numLineEnd = fileEndLine; + + if ( A >= 50 && A < 100) numLineStart = lineMass050_099; + if ( A >=100 && A < 150) numLineStart = lineMass100_149; + if ( A >=150 && A < 200) numLineStart = lineMass150_199; + if ( A >=200 ) numLineStart = lineMass200; + + myfile.open(dataSource.c_str()); + + if (myfile.is_open()) { + while (/*! myfile.eof() &&*/ flag == 0 && lineNum = numLineStart ){ + list_symbol = line.substr(20,2); + list_A = atoi((line.substr(15,5)).c_str()); + + //printf(" A = %d, Sym = |%s| \n", list_A, list_symbol.c_str()); + + if ( this->A == list_A && this->Symbol == list_symbol) { + this->Z = atoi((line.substr(10,5)).c_str()); + this->BEA = atof((line.substr(54,11)).c_str()); + this->Mass = this->Z*mp + (list_A-this->Z)*mn - this->BEA/1000*list_A; + this->MassError = atof((line.substr(65,7)).c_str()); + + string str = line.substr(20,2); + str.erase(remove(str.begin(), str.end(), ' '), str.end()); + this->Symbol = str; + + ostringstream ss; + ss << this->A << this->Symbol; + this->Name = ss.str(); + flag = 1; + }else if ( list_A > this->A) { + this->BEA = -404; + this->Mass = -404; + this->MassError = -404; + this->Symbol = "non"; + this->Name = "non"; + break; + } + + } + } + myfile.close(); + }else { + printf("Unable to open %s\n", dataSource.c_str()); + } +} + +inline double Isotope::CalSp(int Np, int Nn){ + Isotope nucleusD(A - Np - Nn, Z - Np); + + if( nucleusD.Mass != -404){ + return nucleusD.Mass + Nn*mn + Np*mp - this->Mass; + }else{ + return -404; + } +} + +inline double Isotope::CalSp2(int a, int z){ + Isotope nucleusD(A - a , Z - z); + Isotope nucleusS(a,z); + + if( nucleusD.Mass != -404 && nucleusS.Mass != -404){ + return nucleusD.Mass + nucleusS.Mass - this->Mass; + }else{ + return -404; + } +} + +inline int Isotope::TwoJ(int nShell){ + + switch(nShell){ + case 0: return 1; break; // 0s1/2 + case 1: return 3; break; // 0p3/2 + case 2: return 1; break; // 0p1/2 -- 8 + case 3: return 5; break; // 0d5/2 + case 4: return 1; break; // 1s1/2 + case 5: return 3; break; // 0d3/2 -- 20 + case 6: return 7; break; // 0f7/2 -- 28 + case 7: return 3; break; // 1p3/2 + case 8: return 1; break; // 1p1/2 + case 9: return 5; break; // 0f5/2 -- 40 + case 10: return 9; break; // 0g9/2 -- 50 + case 11: return 7; break; // 0g7/2 + case 12: return 5; break; // 1d5/2 + case 13: return 11; break; // 0h11/2 + case 14: return 3; break; // 1d3/2 + case 15: return 1; break; // 2s1/2 -- 82 + case 16: return 9; break; // 0h9/2 + case 17: return 7; break; // 1f7/2 + case 18: return 13; break; // 0i13/2 + case 19: return 3; break; // 2p3/2 + case 20: return 5; break; // 1f5/2 + case 21: return 1; break; // 1p1/2 -- 126 + case 22: return 9; break; // 1g9/2 + case 23: return 11; break; // 0i11/2 + case 24: return 15; break; // 0j15/2 + case 25: return 5; break; // 2d5/2 + case 26: return 1; break; // 3s1/2 + case 27: return 3; break; // 2d3/2 + case 28: return 7; break; // 1g7/2 + } + + return 0; +} + +inline string Isotope::Orbital(int nShell){ + + switch(nShell){ + case 0: return "0s1 "; break; // + case 1: return "0p3 "; break; // + case 2: return "0p1 "; break; //-- 8 + case 3: return "0d5 "; break; // + case 4: return "1s1 "; break; // + case 5: return "0d3 "; break; //-- 20 + case 6: return "0f7 "; break; //-- 28 + case 7: return "1p3 "; break; // + case 8: return "1p1 "; break; // + case 9: return "0f5 "; break; //-- 40 + case 10: return "0g9 "; break; //-- 50 + case 11: return "0g7 "; break; // + case 12: return "1d5 "; break; // + case 13: return "0h11"; break; // + case 14: return "1d3 "; break; // + case 15: return "2s1 "; break; //-- 82 + case 16: return "0h9 "; break; // + case 17: return "1f7 "; break; // + case 18: return "0i13"; break; // + case 19: return "2p3 "; break; // + case 20: return "1f5 "; break; // + case 21: return "1p1 "; break; //-- 126 + case 22: return "1g9 "; break; // + case 23: return "0i11"; break; // + case 24: return "0j15"; break; // + case 25: return "2d5 "; break; // + case 26: return "3s1 "; break; // + case 27: return "2d3 "; break; // + case 28: return "1g7 "; break; // + } + + return "nan"; +} + +inline void Isotope::ListShell(){ + + if( Mass < 0 ) return; + + int n = A-Z; + int p = Z; + + int k = std::min(n,p); + int nMagic = 0; + for( int i = 0; i < 7; i++){ + if( magic(i) < k && k <= magic(i+1) ){ + nMagic = i; + break; + } + } + + int coreShell = magicShellID(nMagic-1); + int coreZ1 = magic(nMagic-1); + int coreZ2 = magic(nMagic); + + Isotope core1( 2*coreZ1, coreZ1); + Isotope core2( 2*coreZ2, coreZ2); + + printf("------------------ Core:%3s, inner Core:%3s \n", (core2.Name).c_str(), (core1.Name).c_str()); + printf(" || "); + int t = std::max(n,p); + int nShell = 0; + do{ + int occ = TwoJ(nShell)+1; + if( nShell > coreShell) { + printf("%4s", Orbital(nShell).c_str()); + if( nShell == 0 || nShell == 2 || nShell == 5 || nShell ==6 || nShell == 9 || nShell == 10 || nShell == 15 || nShell == 21){ + printf("|"); + }else{ + printf(","); + } + } + t = t - occ; + nShell++; + }while( t > 0 && nShell < 29); + for( int i = 1; i <= 6; i++){ + if (nShell < 28) { + printf("%4s,", Orbital(nShell).c_str()); + }else if( nShell == 28 ) { + printf("%4s", Orbital(nShell).c_str()); + } + nShell ++; + } + if (nShell < 29) printf("%4s", Orbital(nShell).c_str()); + printf("\n"); + + + printf(" Z = %3d || ", p); + nShell = 0; + do{ + int occ = TwoJ(nShell)+1; + if( nShell > coreShell ){ + if( p > occ ) { + printf("%-4d", occ); + if( nShell == 0 || nShell == 2 || nShell == 5 || nShell ==6 || nShell == 9 || nShell == 10 || nShell == 15 || nShell == 21){ + printf("|"); + }else{ + printf(","); + } + }else{ + printf("%-4d", p); + } + } + p = p - occ; + nShell++; + }while( p > 0 && nShell < 29); + printf("\n"); + + printf(" N = %3d || ", n); + nShell = 0; + do{ + int occ = TwoJ(nShell)+1; + if ( nShell > coreShell ){ + if( n > occ ) { + printf("%-4d", occ); + if( nShell == 0 || nShell == 2 || nShell == 5 || nShell ==6 || nShell == 9 || nShell == 10 || nShell == 15 || nShell == 21){ + printf("|"); + }else{ + printf(","); + } + }else{ + printf("%-4d", n); + } + } + n = n - occ; + nShell++; + }while( n > 0 && nShell < 29); + printf("\n"); + + printf("------------------ \n"); +} + + +inline void Isotope::Print(){ + + if (Mass > 0){ + + dataSource = massData; + + printf(" using mass data : %s \n", dataSource.c_str()); + printf(" mass of \e[47m\e[31m%s\e[m nucleus (Z,A)=(%3d,%3d) is \e[47m\e[31m%12.5f\e[m MeV, BE/A=%7.5f MeV\n", Name.c_str(), Z, A, Mass, BEA/1000.); + printf(" total BE : %12.5f MeV\n",BEA*A/1000.); + printf(" mass in amu : %12.5f u\n",Mass/amu); + printf(" mass excess : %12.5f MeV\n", Mass + Z*0.510998950 - A*amu); + printf("-------------- Seperation energy \n"); + printf(" S1p: %8.4f| S1n: %8.4f| S(2H ): %8.4f| S1p1n : %8.4f\n", CalSp(1, 0), CalSp(0, 1), CalSp2(2, 1), CalSp(1, 1)); + printf(" S2p: %8.4f| S2n: %8.4f| S(3He): %8.4f| S(3H) : %8.4f\n", CalSp(2, 0), CalSp(0, 2), CalSp2(3, 2), CalSp2(3, 1)); + printf(" S3p: %8.4f| S3n: %8.4f| S(4He): %8.4f|\n", CalSp(3, 0), CalSp(0, 3), CalSp2(4, 2)); + printf(" S4p: %8.4f| S4n: %8.4f| \n", CalSp(4, 0), CalSp(0, 4)); + + }else{ + printf("Error %6.0f, no nucleus with (Z,A) = (%3d,%3d). \n", Mass, Z, A); + } + + +} + +#endif diff --git a/anasen_analysis_vignesh/Armory/LICENSE b/anasen_analysis_vignesh/Armory/LICENSE new file mode 100644 index 0000000..f288702 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/LICENSE @@ -0,0 +1,674 @@ + GNU GENERAL PUBLIC LICENSE + Version 3, 29 June 2007 + + Copyright (C) 2007 Free Software Foundation, Inc. + Everyone is permitted to copy and distribute verbatim copies + of this license document, but changing it is not allowed. + + Preamble + + The GNU General Public License is a free, copyleft license for +software and other kinds of works. + + The licenses for most software and other practical works are designed +to take away your freedom to share and change the works. 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But first, please read +. diff --git a/anasen_analysis_vignesh/Armory/Makefile b/anasen_analysis_vignesh/Armory/Makefile new file mode 100644 index 0000000..9cc4957 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Makefile @@ -0,0 +1,32 @@ +######################################################################## +# +# +######################################################################### + +CC = g++ + +#COPTS = -fPIC -DLINUX -O2 -std=c++17 -lpthread +COPTS = -fPIC -DLINUX -g -O0 -Wall -std=c++17 -lpthread + +ROOTLIBS = `root-config --cflags --glibs` + +ALL = Mapper EventBuilder#AnasenMS + +######################################################################### + +all : $(ALL) + +clean : + /bin/rm -f $(OBJS) $(ALL) + +Mapper : Mapper.cpp ../mapping.h ClassDet.h + @echo "--------- making Mapper" + $(CC) $(COPTS) -o Mapper Mapper.cpp $(ROOTLIBS) + +# AnasenMS : constant.h Isotope.h ClassTransfer.h ClassSX3.h ClassPW.h ClassAnasen.h anasenMS.cpp +# @echo "--------- making ANASEN Monte Carlo" +# $(CC) $(COPTS) -o AnasenMS anasenMS.cpp $(ROOTLIBS) + +EventBuilder : EventBuilder.cpp ../ClassData.h fsuReader.h ../Hit.h + @echo "--------- making EventBuilder" + $(CC) $(COPTS) -o EventBuilder EventBuilder.cpp $(ROOTLIBS) diff --git a/anasen_analysis_vignesh/Armory/Mapper.cpp b/anasen_analysis_vignesh/Armory/Mapper.cpp new file mode 100644 index 0000000..8030de1 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/Mapper.cpp @@ -0,0 +1,182 @@ +#include +#include + +#include +#include +#include +#include +#include + +#include "../mapping.h" +#include "ClassDet.h" + +//=============================== +int main(int argc, char **argv){ + + printf("=========================================\n"); + printf("=== Mapper ===\n"); + printf("=========================================\n"); + if (argc != 2) { + printf("Incorrect number of arguments:\n"); + printf("%s [inFile]\n", argv[0]); + printf("\n\n"); + return 1; + } + + ///============= read input + std::string inFileName = argv[1]; + + PrintMapping(); + + TFile * inFile = new TFile(inFileName.c_str(), "READ"); + TTree * tree = (TTree*) inFile->Get("tree"); + unsigned long long totnumEntry = tree->GetEntries(); + + ULong64_t evID; + UInt_t multi; + UShort_t sn[MAXMULTI]; + UShort_t ch[MAXMULTI]; + UShort_t e[MAXMULTI]; + UShort_t e2[MAXMULTI]; + ULong64_t e_t[MAXMULTI]; + UShort_t e_f[MAXMULTI]; + + tree->SetBranchAddress("evID", &evID); + tree->SetBranchAddress("multi", &multi); + tree->SetBranchAddress("sn", sn); + tree->SetBranchAddress("ch", ch); + tree->SetBranchAddress("e", e); + tree->SetBranchAddress("e2", e2); + tree->SetBranchAddress("e_t", e_t); + tree->SetBranchAddress("e_f", e_f); + + ///================== new tree + TString outFileName = inFileName; + TString runStr = outFileName; + int pos = outFileName.Last('/'); + pos = outFileName.Index("_", pos+1); // find next "_" + runStr.Remove(0, pos+1); + runStr.Remove(3); + pos = outFileName.Index("_", pos+1); // find next "_" + outFileName.Remove(pos); // remove the rest + outFileName += "_mapped.root"; + + ULong_t eventID; + UInt_t run = runStr.Atoi(); + + Det sx3; + Det qqq; + Det pc ; + + printf(" Raw root file : %s\n", inFileName.c_str()); + printf(" Run : %03d\n", run); + printf(" total Entry : %lld \n", totnumEntry); + printf(" Out file name : %s \n", outFileName.Data()); + + TFile * saveFile = new TFile( outFileName,"RECREATE"); + TTree * newTree = new TTree("tree","tree"); + + + newTree->Branch("evID", &eventID,"eventID/l"); + newTree->Branch("run", &run,"run/i"); + + newTree->Branch("sx3Multi", &sx3.multi, "sx3Multi/s"); + newTree->Branch("sx3ID", &sx3.id, "sx3ID[sx3Multi]/s"); + newTree->Branch("sx3Ch", &sx3.ch, "sx3Ch[sx3Multi]/s"); + newTree->Branch("sx3E", &sx3.e, "sx3Energy[sx3Multi]/s"); + newTree->Branch("sx3T", &sx3.t, "sx3Time[sx3Multi]/l"); + + newTree->Branch("qqqMulti", &qqq.multi, "qqqMulti/s"); + newTree->Branch("qqqID", &qqq.id, "qqqID[qqqMulti]/s"); + newTree->Branch("qqqCh", &qqq.ch, "qqqCh[qqqMulti]/s"); + newTree->Branch("qqqE", &qqq.e, "qqqEnergy[qqqMulti]/s"); + newTree->Branch("qqqT", &qqq.t, "qqqTime[qqqMulti]/l"); + newTree->Branch("qqqSN", &qqq.sn, "qqqSN[qqqMulti]/s"); + + newTree->Branch("pcMulti", &pc.multi, "pcMulti/s"); + newTree->Branch("pcID", &pc.id, "pcID[pcMulti]/s"); + newTree->Branch("pcCh", &pc.ch, "pcCh[pcMulti]/s"); + newTree->Branch("pcE", &pc.e, "pcEnergy[pcMulti]/s"); + newTree->Branch("pcT", &pc.t, "pcTime[pcMulti]/l"); + + ///================== looping old tree and apply mapping + + //clock + // TBenchmark clock; + // Bool_t shown; + + for( unsigned long long ev = 0; ev < totnumEntry; ev++){ + tree->GetEntry(ev); + + eventID = evID; + sx3.multi = 0; + qqq.multi = 0; + pc.multi = 0; + + qqq.Clear(); + + for( unsigned int i = 0; i < multi; i++){ + + // printf("%10u/%10u| %5d, %2u, %6u, %14llu\n", i, multi, sn[i], ch[i], e[i], e_t[i] ); + + //globalCh = digi-ID * nCh(digi-iD) + ch + int globalCh = -1; + + for( int j = 0; j < nBd; j++){ + if( board.at(j) == sn[i]){ + globalCh = (sn[i] > 1000 ? j * 64 : 7*64 + (j-7) * 16) + ch[i]; //& = number V1740 + break; + } + } + + if( globalCh == -1) printf("ev %llu\n", ev); + + unsigned short ID = mapping[globalCh]; + + //=================================== sx3 + if( ID < 10000 ) { + sx3.id[sx3.multi] = ID / 100; + sx3.ch[sx3.multi] = ID % 100; + sx3.e[sx3.multi] = e[i]; + sx3.t[sx3.multi] = e_t[i]; + sx3.multi ++; + } + + //=================================== qqq + if( 10000 <= ID && ID < 20000 ) { + qqq.id[qqq.multi] = (ID - 10000) / 100; + qqq.ch[qqq.multi] = (ID - 10000) % 100; + qqq.e[qqq.multi] = e[i]; + qqq.t[qqq.multi] = e_t[i]; + qqq.sn[qqq.multi] = sn[i]; + qqq.multi ++; + } + + //=================================== pc + if( 20000 <= ID && ID < 30000 ) { + pc.id[pc.multi] = (ID - 20000) / 100; + pc.ch[pc.multi] = (ID - 20000) % 100; + pc.e[pc.multi] = e[i]; + pc.t[pc.multi] = e_t[i]; + pc.multi ++; + } + } + + saveFile->cd(); //set focus on this file + newTree->Fill(); + + if( eventID % 100 == 0 ) printf("%6lu/%6llu [%2d%%]\n\033[A\r", eventID, totnumEntry, TMath::Nint((eventID+1)*100./totnumEntry)); + + } + + inFile->Close(); + + saveFile->cd(); //set focus on this file + newTree->Write(); + UInt_t eventNumber = newTree->GetEntries(); + saveFile->Close(); + printf("-------------- done, %u\n", eventNumber); + + return 0; + +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/Armory/SX3Geom.h b/anasen_analysis_vignesh/Armory/SX3Geom.h new file mode 100644 index 0000000..dc7a632 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/SX3Geom.h @@ -0,0 +1,190 @@ +#ifndef SX3Geom_h +#define SX3Geom_h +#include + +const double DEFAULT_NULL=-987654321.; + +class sx3_geometry_scalefactors { +public: + //If sx3 has L, R being the left and right extremities, we choose add, stretch here such that + // x_mm = (x_raw+add)*stretch; so add=abs(L), stretch=75/(abs(L)+R) + float add[4]; + float stretch[4]; +}; + +class qqq5_finegains { +public: + std::array,32> front; + //front.at(30).first = slope at clkpos 0, ring 30 for E front layer + //front.at(30).second = intercept for the same as above + std::array,4> back; +}; +class sx3_fbgains { +public: + //Order of indices is [pad][strip] + float padoffsets[4][4]; + float padgains[4][4]; + + float stripLoffsets[4][4]; + float stripLgains[4][4]; + + float stripRoffsets[4][4]; + float stripRgains[4][4]; +}; + +std::array sx3_xtalk_gains; //every sx3 needs to be gainmatched as a frontL-back, frontR-back pair (pad strip pair) +std::array sx3gs; + +class sx3 { +public: + //TODO: Convert to std::array + //Holds all information in an event, including ped subtraction+scaling. back[2].at(0) will have the largest energy seen in ch2, if any + std::vector back[4]; + std::vector frontL[4]; + std::vector frontR[4]; + + double ts = DEFAULT_NULL; + //Easy lookup of final calibrated event. Only filled for valid cases, assumed for now to be 1L, 1R, 1B + float frontX=DEFAULT_NULL; + float frontXmm=DEFAULT_NULL; + float frontE=DEFAULT_NULL; + float backE=DEFAULT_NULL; + int stripF=DEFAULT_NULL; + int stripB=DEFAULT_NULL; + float frontEL=DEFAULT_NULL; + float frontER=DEFAULT_NULL; + + float phi=DEFAULT_NULL; // + + std::set valid_front_chans; + std::set valid_back_chans; + std::set unmatched_front_chans; //every front channel is unmatched and invalid at first. when it gets matched, it gets removed and sent to valid + + bool foundevent=false; + bool valid=false;//valid will be set to false in all cases where we have ambiguity + int flags=-1;//flags settable to different types of values to indicate different invalid situations + + void fillevent(const std::string& position, const int subchannel, const float value); //make 'const' what functions don't need to change, helps with performance + void validate(const sx3_fbgains&, const sx3_geometry_scalefactors&); + void validate(); +}; + + +void sx3::fillevent(const std::string& positionstring, const int subchannel, const float value) { + assert(subchannel>=0 && subchannel<4); + foundevent=1; + if(positionstring=="FRONT_L") { + frontL[subchannel].push_back(value); + unmatched_front_chans.insert(subchannel); + } else if(positionstring=="FRONT_R") { + frontR[subchannel].push_back(value); + unmatched_front_chans.insert(subchannel); + } else if(positionstring=="BACK") { + back[subchannel].push_back(value); + valid_back_chans.insert(subchannel); + } else { + std::cout << "Unknown string "+positionstring+" encountered in sx3::fillevent \n" << std::endl; + } + if(frontL[subchannel].size()!=0 && frontR[subchannel].size()!=0 ) { + unmatched_front_chans.erase(subchannel); + valid_front_chans.insert(subchannel); //std::set, so no duplication will happen + } +} + + +//void sx3::validate(const sx3_fbgains& fbgains, const sx3_geometry_scalefactors& sx3gs) { +void sx3::validate() { + if(valid_front_chans.size()!=0 && valid_back_chans.size()!=0) { + valid=true; + float maxFE=0; + float maxBE=0; + //float zpos=0; + int bchan=-1; + int fchan=-1; +/* for(auto cc: valid_front_chans) { + std::cout << "fc" << cc << std::endl;// " " << frontL[cc].at(0) << " " << frontR[cc].at(0) << std::endl; + } + for(auto cc: valid_back_chans) { + std::cout << "bc" << cc << std::endl; //" " << back[cc].at(0) << std::endl; + } +*/ + for(auto chan: valid_front_chans) { + if(frontL[chan].size()>1) { + printf("\nmultihit sx3 at Lsubchan:%d, ts:%1.13g\n",chan,ts); + for(const auto& e: frontL[chan]) printf("e: %f\t",e); + std::sort(frontL[chan].begin(), frontL[chan].end(), std::greater()); + flags += (-1000); + } + if(frontR[chan].size()>1) { + printf("\nmultihit sx3 at Rsubchan:%d, ts:%1.13g\n",chan,ts); + for(const auto& e: frontR[chan]) printf("e: %f\t",e); + std::sort(frontR[chan].begin(), frontR[chan].end(), std::greater()); + flags += (-2000); + } + //assign position using max L+R value + /*printf("chan:%d sizeL: %d sizeR: %d\n",chan, frontL[chan].size(), frontR[chan].size()); fflush(stdout); + printf("foo\n"); + std::cout << "\nL:" << std::endl; + for(auto thing: frontL[chan]) std::cout << thing << " " << std::flush; + std::cout << "\nR:" << std::endl; + for(auto thing: frontR[chan]) std::cout << thing << " " << std::flush;*/ + if(frontL[chan].at(0) + frontR[chan].at(0)>= maxFE) { + maxFE = frontL[chan].at(0) + frontR[chan].at(0); + //zpos = (frontL[chan].at(0)-frontR[chan].at(0))/maxFE; + fchan = chan; + } + } + for(auto chan: valid_back_chans) { + if(back[chan].size()>1) { + printf("\nmultihit sx3 at Bsubchan:%d, ts:%1.13g\n",chan,ts); + for(const auto& e: back[chan]) printf("e: %f\t",e); + std::sort(back[chan].begin(), back[chan].end(), std::greater()); + flags += (-3000); + } + if(back[chan].size() ==0 ) { + printf("foo\n"); + //continue; + } + if(back[chan].at(0) >= maxBE) { + maxBE = back[chan].at(0); + bchan = chan; + } + } + /* + Cross-talk corrections are important when evaluating 'energy' signals from strips/pads. + They can cause unexpected behavior when used universally for all EL, ER cases, so we split scenarios in two. + - Positions along each strip (frontX) *are not* corrected for crosstalk. + - Total F and B energies (frontE, backE) *are*. + Sudarsan B, 31 Oct 2024 + */ + + if(fchan==-1 || bchan==-1) { + std::cout << "how" << std::endl; + std::cout << "fc " << std::flush; for(auto fc : valid_front_chans) std::cout << fc << " (" << frontL[fc].at(0) << "," << frontR[fc].at(0)<< ") "; std::cout << std::endl; + std::cout << "bc " << std::flush; for(auto bc : valid_back_chans) std::cout << bc << " " << back[bc].at(0) << std::flush; std::cout << std::endl; + } + float Eleft = frontL[fchan].at(0); + float Eright = frontR[fchan].at(0); + frontEL = Eleft; + frontER = Eright; + frontX = (Eleft-Eright)/(Eleft+Eright); + //frontXmm = (frontX+sx3gs.add[fchan])*sx3gs.stretch[fchan]; //convert to mm + + //frontE = Eleft*fbgains.stripLgains[bchan][fchan] + fbgains.stripLoffsets[bchan][fchan] + // + Eright*fbgains.stripRgains[bchan][fchan] + fbgains.stripRoffsets[bchan][fchan]; + //backE = back[bchan].at(0)*fbgains.padgains[bchan][fchan]+fbgains.padoffsets[bchan][fchan]; + frontE = Eleft+Eright; + backE = maxBE; + stripF=fchan; + stripB=bchan; + + flags = 0; + } else if(valid_front_chans.size()!=0 && valid_back_chans.size()==0) { + flags = -10; + } else if(valid_front_chans.size()==0 && valid_back_chans.size()!=0) { + flags = -20; + } +} + +typedef sx3 sx3det; +#endif diff --git a/anasen_analysis_vignesh/Armory/anasenMS.cpp b/anasen_analysis_vignesh/Armory/anasenMS.cpp new file mode 100644 index 0000000..162e64f --- /dev/null +++ b/anasen_analysis_vignesh/Armory/anasenMS.cpp @@ -0,0 +1,280 @@ +#include "TRandom.h" +#include "TFile.h" +#include "TTree.h" +#include "TH1.h" +#include "TH2.h" +#include "TStyle.h" +#include "TCanvas.h" +#include "TBenchmark.h" + +#include "ClassTransfer.h" +#include "ClassAnasen.h" + +//======== Gerneate light particle based on reaction +// find out the CalTrack and the real track +// find out the Q-value uncertaintly + +int main(int argc, char **argv){ + + printf("=========================================\n"); + printf("=== ANASEN Monte Carlo ===\n"); + printf("=========================================\n"); + + int numEvent = 1000000; + if( argc >= 2 ) numEvent = atoi(argv[1]); + + //Reaction + TransferReaction transfer; + + transfer.SetA(24,12, 0); + transfer.SetIncidentEnergyAngle(10, 0, 0); + transfer.Seta( 4, 2); + transfer.Setb( 1, 1); + + //TODO add alpha source + + std::vector ExAList = {0}; + std::vector ExList = {0, 1, 2}; + + double vertexXRange[2] = { -5, 5}; // mm + double vertexYRange[2] = { -5, 5}; + double vertexZRange[2] = { -100, 100}; + + double sigmaSX3_W = -1; // mm, < 0 use mid-point + double sigmaSX3_L = 3; // mm, < 0 use mid-point + double sigmaPW_A = 0; // from 0 to 1. + double sigmaPW_C = 0; // from 0 to 1. + + //################################################### + + printf("------------ Vertex :\n"); + printf("X : %7.2f - %7.2f mm\n", vertexXRange[0], vertexXRange[1]); + printf("Y : %7.2f - %7.2f mm\n", vertexYRange[0], vertexYRange[1]); + printf("Z : %7.2f - %7.2f mm\n", vertexZRange[0], vertexZRange[1]); + printf("------------ Uncertainty :\n"); + printf(" SX3 horizontal : %.1f\n", sigmaSX3_W); + printf(" SX3 vertical : %.1f\n", sigmaSX3_L); + printf(" Anode : %.1f mm\n", sigmaPW_A); + printf(" Cathode : %.1f mm\n", sigmaPW_C); + printf(" num_eve : %d \n",numEvent); + transfer.CalReactionConstant(); + + int nExA = ExAList.size(); + int nEx = ExList.size(); + + ANASEN * anasen = new ANASEN(); + SX3 * sx3 = anasen->GetSX3(); + PW * pw = anasen->GetPW(); + + TString saveFileName = "SimAnasen1.root"; + printf("\e[32m#################################### building Tree in %s\e[0m\n", saveFileName.Data()); + TFile * saveFile = new TFile(saveFileName, "recreate"); + TTree * tree = new TTree("tree", "tree"); + + double KEA; + tree->Branch("beamKEA", &KEA, "beamKEA/D"); + + double thetaCM, phiCM; + tree->Branch("thetaCM", &thetaCM, "thetaCM/D"); + tree->Branch("phiCM", &phiCM, "phiCM/D"); + + double thetab, phib, Tb; + double thetaB, phiB, TB; + tree->Branch("thetab", &thetab, "thetab/D"); + tree->Branch("phib", &phib, "phib/D"); + tree->Branch("Tb", &Tb, "Tb/D"); + tree->Branch("thetaB", &thetaB, "thetaB/D"); + tree->Branch("phiB", &phiB, "phiB/D"); + tree->Branch("TB", &TB, "TB/D"); + + int ExAID; + double ExA; + tree->Branch("ExAID", &ExAID, "ExAID/I"); + tree->Branch("ExA", &ExA, "ExA/D"); + + int ExID; + double Ex; + tree->Branch("ExID", &ExID, "ExID/I"); + tree->Branch("Ex", &Ex, "Ex/D"); + + double vertexX, vertexY, vertexZ; + tree->Branch("vX", &vertexX, "VertexX/D"); + tree->Branch("vY", &vertexY, "VertexY/D"); + tree->Branch("vZ", &vertexZ, "VertexZ/D"); + + double sx3X, sx3Y, sx3Z; + tree->Branch("sx3X", &sx3X, "sx3X/D"); + tree->Branch("sx3Y", &sx3Y, "sx3Y/D"); + tree->Branch("sx3Z", &sx3Z, "sx3Z/D"); + + int anodeID[2], cathodeID[2]; + tree->Branch("aID", anodeID, "anodeID/I"); + tree->Branch("cID", cathodeID, "cathodeID/I"); + + double anodeDist[2], cathodeDist[2]; + tree->Branch("aDist", anodeDist, "anodeDist/D"); + tree->Branch("cDist", cathodeDist, "cathodeDist/D"); + + int sx3ID, sx3Up, sx3Dn, sx3Bk; + double sx3ZFrac; + tree->Branch("sx3ID", &sx3ID, "sx3ID/I"); + tree->Branch("sx3Up", &sx3Up, "sx3Up/I"); + tree->Branch("sx3Dn", &sx3Dn, "sx3Dn/I"); + tree->Branch("sx3Bk", &sx3Bk, "sx3Bk/I"); + tree->Branch("sx3ZFrac", &sx3ZFrac, "sx3ZFrac/D"); + + double reTheta, rePhi; + tree->Branch("reTheta", &reTheta, "reconstucted_theta/D"); + tree->Branch("rePhi", &rePhi, "reconstucted_phi/D"); + + double reTheta1, rePhi1; + tree->Branch("reTheta1", &reTheta1, "reconstucted_theta1/D"); + tree->Branch("rePhi1", &rePhi1, "reconstucted_phi1/D"); + + double z0; + tree->Branch("z0", &z0, "reconstucted_Z/D"); + + + //========timer + TBenchmark clock; + bool shown ; + clock.Reset(); + clock.Start("timer"); + shown = false; + + //================================= Calculate event + for( int i = 0; i < numEvent ; i++){ + + ExAID = gRandom->Integer(nExA); + ExA = ExAList[ExAID]; + transfer.SetExA(ExA); + + ExID = gRandom->Integer(nEx); + Ex = ExList[ExID]; + transfer.SetExB(Ex); + + transfer.CalReactionConstant(); + + thetaCM = TMath::ACos(2 * gRandom->Rndm() - 1) ; + phiCM = (gRandom->Rndm() - 0.5) * TMath::TwoPi(); + + //==== Calculate reaction + TLorentzVector * output = transfer.Event(thetaCM, phiCM); + TLorentzVector Pb = output[2]; + TLorentzVector PB = output[3]; + + thetab = Pb.Theta() * TMath::RadToDeg(); + thetaB = PB.Theta() * TMath::RadToDeg(); + + Tb = Pb.E() - Pb.M(); + TB = PB.E() - PB.M(); + + phib = Pb.Phi() * TMath::RadToDeg(); + phiB = PB.Phi() * TMath::RadToDeg(); + + vertexX = (vertexXRange[1]- vertexXRange[0])*gRandom->Rndm() + vertexXRange[0]; + vertexY = (vertexYRange[1]- vertexYRange[0])*gRandom->Rndm() + vertexYRange[0]; + vertexZ = (vertexZRange[1]- vertexZRange[0])*gRandom->Rndm() + vertexZRange[0]; + + TVector3 vertex(vertexX, vertexY, vertexZ); + + TVector3 dir(1, 0, 0); + dir.SetTheta(thetab * TMath::DegToRad()); + dir.SetPhi(phib * TMath::DegToRad()); + + + pw->FindWireID(vertex, dir, false); + sx3->FindSX3Pos(vertex, dir, false); + + PWHitInfo hitInfo = pw->GetHitInfo(); + + anodeID[0] = hitInfo.nearestWire.first; + cathodeID[0] = hitInfo.nearestWire.second; + anodeID[1] = hitInfo.nextNearestWire.first; + cathodeID[1] = hitInfo.nextNearestWire.second; + + anodeDist[0] = hitInfo.nearestDist.first; + cathodeDist[0] = hitInfo.nearestDist.second; + anodeDist[1] = hitInfo.nextNearestDist.first; + cathodeDist[1] = hitInfo.nextNearestDist.second; + + sx3ID = sx3->GetID(); + if( sx3ID >= 0 ){ + sx3Up = sx3->GetChUp(); + sx3Dn = sx3->GetChDn(); + sx3Bk = sx3->GetChBk(); + sx3ZFrac = sx3->GetZFrac(); + + //Introduce uncertaity + // TVector3 hitPos = sx3->GetHitPos(); + TVector3 hitPos = sx3->GetHitPosWithSigma(sigmaSX3_W, sigmaSX3_L); + + sx3X = hitPos.X(); + sx3Y = hitPos.Y(); + sx3Z = hitPos.Z(); + + pw->CalTrack(hitPos, anodeID[0], cathodeID[0], false); + reTheta = pw->GetTrackTheta() * TMath::RadToDeg(); + rePhi = pw->GetTrackPhi() * TMath::RadToDeg(); + + pw->CalTrack2(hitPos, hitInfo, sigmaPW_A, sigmaPW_C, false); + reTheta1 = pw->GetTrackTheta() * TMath::RadToDeg(); + rePhi1 = pw->GetTrackPhi() * TMath::RadToDeg(); + + z0 = pw->GetZ0(); + + }else{ + sx3Up = -1; + sx3Dn = -1; + sx3Bk = -1; + sx3ZFrac = TMath::QuietNaN(); + + sx3X = TMath::QuietNaN(); + sx3Y = TMath::QuietNaN(); + sx3Z = TMath::QuietNaN(); + + // for( int i = 0; i < 12; i++){ + // sx3Index[i] = -1; + // } + + reTheta = TMath::QuietNaN(); + rePhi = TMath::QuietNaN(); + + reTheta1 = TMath::QuietNaN(); + rePhi1 = TMath::QuietNaN(); + + z0 = TMath::QuietNaN(); + + } + + tree->Fill(); + + //#################################################################### Timer + clock.Stop("timer"); + Double_t time = clock.GetRealTime("timer"); + clock.Start("timer"); + + if ( !shown ) { + if (fmod(time, 10) < 1 ){ + printf( "%10d[%2d%%]| %8.2f sec | expect: %5.1f min \n", i, TMath::Nint((i+1)*100./numEvent), time , numEvent*time/(i+1)/60); + shown = 1; + } + }else{ + if (fmod(time, 10) > 9 ){ + shown = 0; + } + } + + } + + tree->Write(); + int count = tree->GetEntries(); + saveFile->Close(); + + printf("=============== done. saved as %s. count(hit==1) : %d\n", saveFileName.Data(), count); + + delete anasen; + + return 0; + +} diff --git a/anasen_analysis_vignesh/Armory/constant.h b/anasen_analysis_vignesh/Armory/constant.h new file mode 100644 index 0000000..db83ec5 --- /dev/null +++ b/anasen_analysis_vignesh/Armory/constant.h @@ -0,0 +1,105 @@ +/*********************************************************************** + * + * This is constant.h, to provide various physical constants. + * + *------------------------------------------------------- + * created by Ryan (Tsz Leung) Tang, Nov-18, 2018 + * email: goluckyryan@gmail.com + * ********************************************************************/ + +#ifndef constant +#define constant +#include + +const double pi = acos(-1.0); +const double E = 2.718281828459 ; +const double hbar_SI = 1.054571628e-34; //Js +const double kB = 1.3806504e-23; //JK^-1 +const double e = 1.602176487e-19; //C +const double c_SI = 299792458; //ms^-1 +const double me_SI = 9.10938215e-31 ; //kg +const double mp_SI = 1.672621637e-27 ; //kg +const double mn_SI = 1.67492729e-27 ; //kg +const double NA = 6.022141e+23 ; //mol^-1 + +const double deg2rad = pi/180 ; +const double rad2deg = 180/pi ; + +//====================================================================== +const double amu = 931.49432; // MeV/c^2 +const double hbarc = 197.326979; // MeV fm; +const double c = 299.792458; // mm/ns; +const double ee = 1.439964454; // MeV.fm + +//====================================================================== +double kg2MeV(double m){ + return m*c_SI*c_SI/e/1e6; +} + +double T2Brho(double mass, int Z, int A, double T){ + //mass in MeV + // Z in e + // T in MeV/A + double gamma = (T*A + mass)/mass; + double beta = sqrt(1-1/gamma/gamma); + return mass*beta*gamma/Z/c; +} + +double Brho2T(double mass, int Z, int A, double Brho){ + //mass in MeV + // Z in e + return (sqrt(pow(Brho*Z*c,2)+mass*mass)-mass)/A; +} + +double T2beta(double mass, int A, double T){ + double gamma = 1.0 + T*A/mass; + return sqrt(1-1/gamma/gamma); +} + +double ev2nm(double eV){ + // photon energy to nm + return hbarc/2/pi/eV; +} + +//====================================================================== +const double mp = kg2MeV(mp_SI); +const double mn = kg2MeV(mn_SI); +const double hbar = 197.326979; + + +//====================================================================== +inline std::vector SplitStr(std::string tempLine, std::string splitter, int shift = 0){ + + std::vector output; + + size_t pos; + do{ + pos = tempLine.find(splitter); /// fine splitter + if( pos == 0 ){ ///check if it is splitter again + tempLine = tempLine.substr(pos+1); + continue; + } + + std::string secStr; + if( pos == std::string::npos ){ + secStr = tempLine; + }else{ + secStr = tempLine.substr(0, pos+shift); + tempLine = tempLine.substr(pos+shift); + } + + ///check if secStr is begin with space + while( secStr.substr(0, 1) == " ") secStr = secStr.substr(1); + + ///check if secStr is end with space + while( secStr.back() == ' ') secStr = secStr.substr(0, secStr.size()-1); + + output.push_back(secStr); + ///printf(" |%s---\n", secStr.c_str()); + + }while(pos != std::string::npos ); + + return output; +} + +#endif diff --git a/anasen_analysis_vignesh/Calibration.C b/anasen_analysis_vignesh/Calibration.C new file mode 100644 index 0000000..02f830d --- /dev/null +++ b/anasen_analysis_vignesh/Calibration.C @@ -0,0 +1,270 @@ + +#define Calibration_cxx + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "Armory/HistPlotter.h" +#include "TVector3.h" +#include "Calibration.h" + +TH2F *hQQQFVB; +HistPlotter *plotter; +int padID = 0; + +TCutG *cut; +std::map, std::vector>> dataPoints; + +bool qqqEcut = false; + +// Gain Arrays +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqwGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +// double qqqrGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqwGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +// bool qqqrGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; + +void Calibration::Begin(TTree * /*tree*/) +{ + plotter = new HistPlotter("Calib.root", "TFILE"); + // ----------------------- Load QQQ Gains + { + std::string filename = "qqq_GainMatch.txt"; + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + } + else + { + int det, ring, wedge; + double gainw, gainr; + while (infile >> det >> ring >> wedge >> gainw >> gainr) + { + qqqwGain[det][ring][wedge] = gainw; + // qqqrGain[det][ring][wedge] = gainr; + qqqwGainValid[det][ring][wedge] = (gainw > 0); + // qqqrGainValid[det][ring][wedge] = (gainr > 0); + } + infile.close(); + std::cout << "Loaded QQQ gains from " << filename << std::endl; + } + } + for (int det = 0; det < MAX_QQQ; det++) + { + for (int ring = 0; ring < MAX_RING; ring++) + { + for (int wedge = 0; wedge < MAX_WEDGE; wedge++) + { + TString hname = Form("hCal_qqq%d_ring%d_wedge%d", det, ring, wedge); + TString htitle = Form("QQQ det%d ring%d wedge%d; Energy (arb); Counts", det, ring, wedge); + // hQQQSpectra[det][ring][wedge] = new TH1F(hname, htitle, 4000, 0, 16000); + } + } + } +} + +Bool_t Calibration::Process(Long64_t entry) +{ + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + + qqq.CalIndex(); + + for (int i = 0; i < qqq.multi; i++) + { + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.e[i] > 100) + qqqEcut = true; + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + float eWedgeRaw = 0.0; + float eWedge = 0.0; + float eRingRaw = 0.0; + float eRing = 0.0; + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && /*qqqrGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16] &&*/ qqqwGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedgeRaw = qqq.e[i]; + eWedge = qqq.e[i] * qqqwGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + // printf("Wedge E: %.2f Gain: %.4f \n", eWedge, qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]); + chRing = qqq.ch[j] - 16; + eRingRaw = qqq.e[j]; + eRing = qqq.e[j];// * qqqrGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && /*qqqrGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16] &&*/ qqqwGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqwGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + eWedgeRaw = qqq.e[j]; + + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i];// * qqqrGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + eRingRaw = qqq.e[i]; + } + else + continue; + + // hQQQFVB->Fill(eWedge, eRing); + plotter->Fill2D(Form("hRaw_qqq%d_ring%d_wedge%d", qqq.id[i], chRing, chWedge), 400, 0, 16000, 400, 0, 16000, eWedgeRaw, eRingRaw, "ERaw"); + plotter->Fill2D(Form("hGM_qqq%d_ring%d_wedge%d", qqq.id[i], chRing, chWedge), 400, 0, 16000, 400, 0, 16000, eWedge, eRing, "EGM"); + plotter->Fill2D("hRawQQQ", 4000, 0, 16000, 4000, 0, 16000, eWedgeRaw, eRingRaw); + plotter->Fill2D("hGMQQQ", 4000, 0, 16000, 4000, 0, 16000, eWedge, eRing); + + TString histName = Form("hQQQFVB_id%d_r%d_w%d", qqq.id[i], chRing, chWedge); + // TH2F *hist2d = (TH2F *)gDirectory->Get(histName); + // if (!hist2d) + // { + // hist2d = new TH2F(histName, Form("QQQ Det%d R%d W%d;Wedge E;Ring E", qqq.id[i], chRing, chWedge), 400, 0, 16000, 400, 0, 16000); + // } + + // hist2d->Fill(eWedge, eRing); + // if (cut && cut->IsInside(eWedge, eRing)) + const double MIN_ADC = 1500.0; + const double MAX_ADC = 3000.0; + + // if (eWedge >= MIN_ADC && eWedge <= MAX_ADC && + // eRing >= MIN_ADC && eRing <= MAX_ADC) + double ratio = (eWedge > 0.0) ? (eRing / eWedge) : 0.0; + + double maxslope = 1.5; + + bool validPoint = false; + if (ratio < maxslope && ratio > 1. / maxslope) + { + // Accumulate data for gain matching + dataPoints[{qqq.id[i], chRing, chWedge}].emplace_back(eWedge, eRing); + } + } + } + } + + return kTRUE; +} + +void Calibration::Terminate() +{ + const double AM241_PEAK = 5485.56; + const double P_PEAK = 7000; // keV + + double calibArray[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; + bool calibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; + + std::ofstream outFile("qqq_Calib.txt"); + if (!outFile.is_open()) + { + std::cerr << "Error opening qqq_Calib.txt!" << std::endl; + return; + } + + //---------------------------------------------------------------------- + // 1. Create per–channel 1D spectra in ADC from stored gain-matched data + //---------------------------------------------------------------------- + + std::map, TH1F *> spectra; + + for (auto &kv : dataPoints) + { + int det, ring, wedge; + std::tie(det, ring, wedge) = kv.first; + + TString hname = Form("hSpec_d%d_r%d_w%d", det, ring, wedge); + TH1F *h = new TH1F(hname, hname, 4000, 0, 16000); + + for (auto &p : kv.second) + { + double eWedge = p.first; // already gain-matched ADC + double eRing = p.second; + + // Use ring ADC for calibration (cleaner alpha peak) + h->Fill(eRing); + } + + spectra[kv.first] = h; + } + + //---------------------------------------------------------------------- + // 2. Fit Am-241 peak and extract keV/ADC calibration slope + //---------------------------------------------------------------------- + + for (auto &kv : spectra) + { + int det, ring, wedge; + std::tie(det, ring, wedge) = kv.first; + TH1F *h = kv.second; + + if (!h || h->GetEntries() < 50) + continue; + + int binMax = h->GetMaximumBin(); + double adcPeak = h->GetXaxis()->GetBinCenter(binMax); + + if (adcPeak <= 0) + continue; + + // double slope_keV = AM241_PEAK / adcPeak; // keV per ADC + double slope_keV = P_PEAK / adcPeak; // keV per ADC + + calibArray[det][ring][wedge] = slope_keV; + calibValid[det][ring][wedge] = true; + + outFile << det << " " << wedge << " " << ring << " " + << slope_keV << "\n"; + + // printf("QQQ DET=%d R=%d W=%d ADCpeak=%.1f slope_keV=%.6f\n",det, ring, wedge, adcPeak, slope_keV); + } + + outFile.close(); + std::cout << "Wrote QQQ calibration file qqq_Calib.txt\n"; + + //---------------------------------------------------------------------- + // 3. Build fully calibrated 2D combined histogram + //---------------------------------------------------------------------- + + TH2F *hCal = new TH2F("hCal", + "All QQQ Calibrated;Wedge Energy (keV);Ring Energy (keV)", + 800, 0, 7000, + 800, 0, 7000); + + for (auto &kv : dataPoints) + { + int det, ring, wedge; + std::tie(det, ring, wedge) = kv.first; + + if (!calibValid[det][ring][wedge]) + continue; + + double slope = calibArray[det][ring][wedge]; + + for (auto &p : kv.second) + { + double eWGM = p.first; // gain matched ADC + double eRGM = p.second; + + double eWkeV = eWGM * slope / 1000; + double eRkeV = eRGM * slope / 1000; + + hCal->Fill(eWkeV, eRkeV); + plotter->Fill2D("hCalQQQ", 4000, 0, 10, 4000, 0, 10, eWkeV, eRkeV); + plotter->Fill2D(Form("hRCal_qqq%d", det), 16, 0, 15, 400, 0, 24, ring, eRkeV, "RingCal"); + plotter->Fill2D(Form("hWCal_qqq%d", det), 16, 0, 15, 400, 0, 24, wedge, eWkeV, "WedgeCal"); + } + } + + plotter->FlushToDisk(); + std::cout << "Calibrated 2D QQQ histogram saved.\n"; +} diff --git a/anasen_analysis_vignesh/Calibration.h b/anasen_analysis_vignesh/Calibration.h new file mode 100644 index 0000000..202d1dd --- /dev/null +++ b/anasen_analysis_vignesh/Calibration.h @@ -0,0 +1,114 @@ +#ifndef Calibration_h +#define Calibration_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class Calibration : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + + Calibration(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~Calibration() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(Calibration,0); +}; + +#endif + +#ifdef Calibration_cxx +void Calibration::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + +} + +Bool_t Calibration::Notify(){ + + return kTRUE; +} + +void Calibration::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void Calibration::SlaveTerminate(){ + +} + + +#endif // #ifdef Calibration_cxx \ No newline at end of file diff --git a/anasen_analysis_vignesh/DataDump.C b/anasen_analysis_vignesh/DataDump.C new file mode 100644 index 0000000..0ae4a7a --- /dev/null +++ b/anasen_analysis_vignesh/DataDump.C @@ -0,0 +1,639 @@ +#define DataDump_cxx + +#include "DataDump.h" +#include "Armory/ClassPW.h" +#include "Armory/HistPlotter.h" + +#include +#include +#include +#include +#include +#include "TVector3.h" + +#include +#include +#include +#include +#include +#include +#include +#include + +// Global instances +PW pw_contr; +PW pwinstance; +TVector3 hitPos; +long long int gcount=0; + +class Event { +public: + TVector3 pos; + int ch1=-1; //ring# for QQQ, anode# for PC + int ch2=-1; //wedge# for QQQ, cathode# for PC + double Energy1=-1; //Front for QQQ, Anode for PC + double Energy2=-1; //Back for QQQ, Cathode for PC + double Time1=-1; + double Time2=-1; + Event(TVector3 p, double E1, double E2, double T1, double T2): pos(p), Energy1(E1), Energy2(E2), Time1(T1), Time2(T2) {} +}; +/* +void testfunction() +{ + for(auto cathode: cathodes) { + std::unordered_set chans; + chans.insert(cathode.ch); + } +} +*/ +// Calibration globals +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +// TCutg *cutQQQ; + +// PC Arrays +double pcSlope[48]; +double pcIntercept[48]; + +HistPlotter *plotter; + +bool HitNonZero; +bool sx3ecut; +bool qqqEcut; + + +void DataDump::Begin(TTree * /*tree*/) +{ + TString option = GetOption(); + plotter = new HistPlotter("Analyzer_QQQ.root", "TFILE"); + + pw_contr.ConstructGeo(); + pwinstance.ConstructGeo(); + + // --------------------------------------------------------- + // 1. CRITICAL FIX: Initialize PC Arrays to Default (Raw) + // --------------------------------------------------------- + for (int i = 0; i < 48; i++) { + pcSlope[i] = 1.0; // Default slope = 1 (preserves Raw energy) + pcIntercept[i] = 0.0; // Default intercept = 0 + } + + // Calculate Crossover Geometry ONCE + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha; + + for (size_t i = 0; i < pwinstance.An.size(); i++) + { + a = pwinstance.An[i].first - pwinstance.An[i].second; + for (size_t j = 0; j < pwinstance.Ca.size(); j++) + { + c = pwinstance.Ca[j].first - pwinstance.Ca[j].second; + diff = pwinstance.An[i].first - pwinstance.Ca[j].first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + + Crossover[i][j][0].x = pwinstance.An[i].first.X() + alpha * a.X(); + Crossover[i][j][0].y = pwinstance.An[i].first.Y() + alpha * a.Y(); + Crossover[i][j][0].z = pwinstance.An[i].first.Z() + alpha * a.Z(); + + if (Crossover[i][j][0].z < -190 || Crossover[i][j][0].z > 190 || (i+j)%24 == 12 ) + { + Crossover[i][j][0].z = 9999999; + } + + Crossover[i][j][1].x = alpha; + Crossover[i][j][1].y = 0; + } + } + + // Load PC Calibrations + std::ifstream inputFile("slope_intercept_results.txt"); + if (inputFile.is_open()) + { + std::string line; + int index; + double slope, intercept; + while (std::getline(inputFile, line)) + { + std::stringstream ss(line); + ss >> index >> slope >> intercept; + if (index >= 0 && index <= 47) + { + pcSlope[index] = slope; + pcIntercept[index] = intercept; + } + } + inputFile.close(); + } + else + { + std::cerr << "Error opening slope_intercept.txt" << std::endl; + } + + // ... (Load QQQ Gains and Calibs - same as before) ... + { + std::string filename = "qqq_GainMatch.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double gainw, gainr; + while (infile >> det >> wedge >> ring >> gainw >> gainr) + { + qqqGain[det][wedge][ring] = gainw; + qqqGainValid[det][wedge][ring] = (gainw > 0); + } + infile.close(); + } + } + { + std::string filename = "qqq_Calib.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double slope; + while (infile >> det >> wedge >> ring >> slope) + { + qqqCalib[det][wedge][ring] = slope; + qqqCalibValid[det][wedge][ring] = (slope > 0); + } + infile.close(); + } + } +} + +Bool_t DataDump::Process(Long64_t entry) +{ + hitPos.Clear(); + HitNonZero = false; + bool qqq1000cut = false; + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + // QQQ Processing + int qqqCount = 0; + int qqqAdjCh = 0; + // REMOVE WHEN RERUNNING USING THE NEW CALIBRATION FILE + for (int i = 0; i < qqq.multi; i++) + { + if ((qqq.id[i] == 3 || qqq.id[i] == 1) && qqq.ch[i] < 16) + { + qqq.ch[i] = 16 - qqq.ch[i]; + } + } + for (int i = 0; i < qqq.multi; i++) + { + if (qqq.id[i] == 0 && qqq.ch[i] >= 16) + { + qqq.ch[i] = 31 - qqq.ch[i] + 16; + } + } + + std::vector> qqqlist; + std::vector QQQ_Events, PC_Events; + std::vector QQQ_Events_Raw, PC_Events_Raw; + bool PCQQQTimeCut = false; + for (int i = 0; i < qqq.multi; i++) + { + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + qqqCount++; + + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + double tWedge = 0.0; + + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + tWedge = static_cast(qqq.t[i]); + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i]; + tRing = static_cast(qqq.t[i]); + tWedge = static_cast(qqq.t[j]); + } + else + continue; + + if (qqqCalibValid[qqq.id[i]][chWedge][chRing]) { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + } + else + continue; + + double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + double rho = 50. + 40. / 16. * (chRing + 0.5); + + Event qqqevent(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),23+75+30), eRingMeV, eWedgeMeV, tRing, tWedge); + Event qqqeventr(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),23+75+30), eRing, eWedge, tRing, tWedge); + QQQ_Events.push_back(qqqevent); + QQQ_Events_Raw.push_back(qqqeventr); + qqqlist.push_back(std::tuple(qqq.id[i],chRing,eRingMeV,chWedge,eWedgeMeV)); + } //end if qqq.id[i] == qqq.id[j] + }//inner qqq loop, j + }//outer qqq loop, i + + // PC Gain Matching and Filling + double anodeT = -99999; + double cathodeT = 99999; + int anodeIndex = -1; + int cathodeIndex = -1; + + + int aID = 0; + int cID = 0; + double aE = 0; + double cE = 0; + double aESum = 0; + double cESum = 0; + double aEMax = 0; + int aIDMax = 0; + anodeHits.clear(); + cathodeHits.clear(); + anodeTimes.clear(); + cathodeTimes.clear(); + corrcatMax.clear(); + corranoMax.clear(); + + std::array caths_seen{0}, anos_seen{0}; + std::vector> anodeChunks, cathodeChunks; + for (int i = 0; i < pc.multi; i++) + { + if (pc.e[i] > 4) + { + ;//plotter->Fill2D("PC_Index_Vs_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], static_cast(pc.e[i]), "hRawPC"); + } else + continue; + + if (pc.index[i] < 48) { + pc.e[i] = pcSlope[pc.index[i]] * pc.e[i] + pcIntercept[pc.index[i]]; + //plotter->Fill2D("PC_Index_VS_GainMatched_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], pc.e[i], "hGMPC"); + } + + if (pc.index[i] < 24) { + anodeT = static_cast(pc.t[i]); + anodeIndex = pc.index[i]; + anos_seen[anodeIndex] = 1; + anodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + anodeTimes.push_back(anodeT); + anodeChunks.push_back(std::tuple(pc.index[i],anodeT,pc.e[i])); + } else { + cathodeT = static_cast(pc.t[i]); + cathodeIndex = pc.index[i] - 24; + caths_seen[cathodeIndex] = 1; + cathodeChunks.push_back(std::tuple(pc.index[i]-24,cathodeT,pc.e[i])); + cathodeHits.push_back(std::pair(pc.index[i] - 24, pc.e[i])); + cathodeTimes.push_back(cathodeT); + } + }//end of pc.multi loop + + if(anodeHits.size() && cathodeHits.size()) { + for(size_t ii=0; iiFill2D("ach_minus_cch_vs_ach",60,-30,30,24,0,24,an.first-ca.first,an.first); + plotter->Fill2D("ach_minus_cch_vs_dt",60,-30,30,400,-1000,1000,an.first-ca.first,at-ct); + plotter->Fill2D("ach_vs_cch",24,0,24,24,0,24,an.first,ca.first); + } + } + gcount++; + } + bool all_three = anodeHits.size() > 0 && cathodeHits.size() > 0 && qqqlist.size() > 0; + + if(all_three) std::cout << "---" << std::endl; + for(size_t ii=0; ii= 1 && cathodeHits.size() >= 1) + { + // 2. CRITICAL FIX: Define reference vector 'a' + // In Analyzer.cxx, 'a' was left over from the loop. We use the first anode wire as reference here. + // (Assuming pwinstance.An is populated and wires are generally parallel). + TVector3 refAnode = pwinstance.An[0].first - pwinstance.An[0].second; + for (const auto &anode : anodeHits) + { + aID = anode.first; + aE = anode.second; + aESum += aE; + if (aE > aEMax) + { + aEMax = aE; + aIDMax = aID; + } + } + + for (const auto &cathode : cathodeHits) + { + cID = cathode.first; + cE = cathode.second; + for (int j = -4; j < 3; j++) + { + if ((aIDMax + 24 + j) % 24 == 23 - cID) + { + corrcatMax.push_back(std::pair(cID, cE)); + cESum += cE; + } + } + } + } + + TVector3 anodeIntersection; + anodeIntersection.Clear(); + if (corrcatMax.size() > 0) + { + double x = 0, y = 0, z = 0; + for (const auto &corr : corrcatMax) + { + if (Crossover[aIDMax][corr.first][0].z > 9000000) + continue; + if (cESum > 0) + { + x += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].x; + y += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].y; + z += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].z; + } + } + if (x == 0 && y == 0 && z == 0) + ; + // to ignore events with no valid crossover points + else + anodeIntersection = TVector3(x, y, z); + } + bool PCQQQPhiCut = false; + // flip the algorithm for cathode 1 multi anode events + if ((hitPos.Phi() > (anodeIntersection.Phi() - TMath::PiOver4())) && (hitPos.Phi() < (anodeIntersection.Phi() + TMath::PiOver4()))) { + PCQQQPhiCut = true; + } + + if (anodeIntersection.Z() != 0) + { + plotter->Fill1D("PC_Z_Projection", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("Z_Proj_VsDelTime", 600, -300, 300, 200, -2000, 2000, anodeIntersection.Z(), anodeT - cathodeT, "hPCzQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi", 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("Inttheta_vs_QQQtheta", 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut), 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() >= 2) + plotter->Fill1D("PC_Z_Projection_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 1) + { + plotter->Fill1D("PC_Z_proj_1C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_1C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill1D("PC_Z_proj_2C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_2C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() > 2) + { + plotter->Fill1D("PC_Z_proj_nC", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_nC", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + plotter->Fill2D("AHits_vs_CHits", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // make another plot with nearest neighbour constraint + bool hasNeighbourAnodes = false; + bool hasNeighbourCathodes = false; + + // 1. Check Anodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < anodeHits.size(); i++) + { + for (size_t j = i + 1; j < anodeHits.size(); j++) + { + int diff = std::abs(anodeHits[i].first - anodeHits[j].first); + if (diff == 1 || diff == 23) + { // 23 handles the cylindrical wrap + hasNeighbourAnodes = true; + break; + } + } + if (hasNeighbourAnodes) + break; + } + + // 2. Check Cathodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < cathodeHits.size(); i++) + { + for (size_t j = i + 1; j < cathodeHits.size(); j++) + { + int diff = std::abs(cathodeHits[i].first - cathodeHits[j].first); + if (diff == 1 || diff == 23) + { + hasNeighbourCathodes = true; + break; + } + } + if (hasNeighbourCathodes) + break; + } + + // --------------------------------------------------------- + // FILL PLOTS + // --------------------------------------------------------- + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + { + plotter->Fill2D("AHits_vs_CHits_NA" + std::to_string(hasNeighbourAnodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + plotter->Fill2D("AHits_vs_CHits_NC" + std::to_string(hasNeighbourCathodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // Constraint Plot: Only fill if BOTH planes have adjacent hits + // This effectively removes events with only isolated single-wire hits (noise) + if (hasNeighbourAnodes && hasNeighbourCathodes) + { + plotter->Fill2D("AHits_vs_CHits_NN", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + } + } + + if (HitNonZero && anodeIntersection.Z() != 0) + { + pw_contr.CalTrack2(hitPos, anodeIntersection); + plotter->Fill1D("VertexRecon", 600, -300, 300, pw_contr.GetZ0()); + plotter->Fill1D("VertexRecon_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -300, 300, pw_contr.GetZ0()); + + if (cathodeHits.size() == 2) + plotter->Fill1D("VertexRecon_2c_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -300, 300, pw_contr.GetZ0()); + } + + for (int i = 0; i < qqq.multi; i++) + { + if (PCQQQTimeCut) + { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + int qqqID = -1; + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + qqqID = qqq.id[i]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + tRing = static_cast(qqq.t[i]); + eRing = qqq.e[i]; + qqqID = qqq.id[i]; + } + else + continue; + + if (qqqCalibValid[qqq.id[i]][chRing][chWedge]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + } + else + continue; + + // if (anodeIntersection.Z() != 0) + { + plotter->Fill2D("PC_Z_vs_QQQRing", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill2D("PC_Z_vs_QQQRing_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQRing_2C" + std::to_string(qqq.id[i]), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQWedge_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chWedge, "hPCzQQQ"); + } + plotter->Fill2D("Vertex_V_QQQRingTC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, 16, 0, 16, pw_contr.GetZ0(), chRing, "hPCQQQ"); + double phi = TMath::ATan2(anodeIntersection.Y(), anodeIntersection.X()) * 180. / TMath::Pi(); + plotter->Fill2D("PolarAngle_Vs_QQQWedge" + std::to_string(qqqID), 360, -360, 360, 16, 0, 16, phi, chWedge, "hPCQQQ"); + // plotter->Fill2D("EdE_PC_vs_QQQ_timegate_ls1000"+std::to_string()) + + plotter->Fill2D("PC_Z_vs_QQQRing_Det" + std::to_string(qqqID), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCQQQ"); + //double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + //double rho = 50. + 40. / 16. * (chRing + 0.5); + + for (int k = 0; k < pc.multi; k++) + { + if(pc.index[k] >= 24) + continue; + + double sinTheta = TMath::Sin(hitPos.Theta()); + + plotter->Fill2D("CalibratedQQQE_RvsPCE_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 1000, 0, 10, 2000, 0, 30000, eRingMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsPCE_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 1000, 0, 10, 2000, 0, 30000, eWedgeMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("PCQQQ_dTimevsdPhi", 200, -2000, 2000, 80, -200, 200, tRing - static_cast(pc.t[k]), (hitPos.Phi()-anodeIntersection.Phi()) * 180. / TMath::Pi(), "hTiming"); + } + } + } + } + for (int i = 0; i < sx3.multi; i++) + { + // plotting sx3 strip hits vs anode phi + if (sx3.ch[i] < 8) + plotter->Fill2D("AnodePhi_vs_SX3Strip", 100, -200, 200, 8 * 24, 0, 8 * 24, anodeIntersection.Phi() * 180. / TMath::Pi(), sx3.id[i] * 8 + sx3.ch[i]); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 3) + { + plotter->Fill1D("PC_Z_proj_3C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + } + + plotter->Fill2D("AnodeMaxE_Vs_Cathode_Sum_Energy", 2000, 0, 30000, 2000, 0, 30000, aEMax, cESum, "hGMPC"); + plotter->Fill1D("Correlated_Cathode_MaxAnode", 6, 0, 5, corrcatMax.size(), "hGMPC"); + plotter->Fill2D("Correlated_Cathode_VS_MaxAnodeEnergy", 6, 0, 5, 2000, 0, 30000, corrcatMax.size(), aEMax, "hGMPC"); + plotter->Fill1D("AnodeHits", 12, 0, 11, anodeHits.size(), "hGMPC"); + plotter->Fill2D("AnodeMaxE_vs_AnodeHits", 12, 0, 11, 2000, 0, 30000, anodeHits.size(), aEMax, "hGMPC"); + + if (anodeHits.size() < 1) + { + plotter->Fill1D("NoAnodeHits_CathodeHits", 6, 0, 5, cathodeHits.size(), "hGMPC"); + } + + return kTRUE; +} + +void DataDump::Terminate() +{ + plotter->FlushToDisk(); +} diff --git a/anasen_analysis_vignesh/DataDump.h b/anasen_analysis_vignesh/DataDump.h new file mode 100644 index 0000000..4091c27 --- /dev/null +++ b/anasen_analysis_vignesh/DataDump.h @@ -0,0 +1,132 @@ +#ifndef DataDump_h +#define DataDump_h + +#include +#include +#include +#include +#include +#include +#include // Required for vectors +#include // Required for std::pair + +#include "Armory/ClassDet.h" +#include "Armory/ClassPW.h" // YOU ADDED THIS (Correct! Defines Coord) + +class DataDump : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + Det misc; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + TBranch *b_miscMulti; //! + TBranch *b_miscID; //! + TBranch *b_miscCh; //! + TBranch *b_miscE; //! + TBranch *b_miscT; //! + TBranch *b_miscTf; //! + + // 1. Geometry Cache + Coord Crossover[24][24][2]; + + // 2. Persistent Vectors (REQUIRED for the optimized .cxx to work) + std::vector> anodeHits; + std::vector> cathodeHits; + std::vector> corrcatMax; + std::vector> corranoMax; + std::vector cathodeTimes; + std::vector anodeTimes; + + DataDump(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~DataDump() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(DataDump,0); +}; + +#endif + +#ifdef DataDump_cxx +void DataDump::Init(TTree *tree){ + + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + fChain->SetBranchAddress("miscMulti", &misc.multi, &b_miscMulti); + fChain->SetBranchAddress("miscID", &misc.id, &b_miscID); + fChain->SetBranchAddress("miscCh", &misc.ch, &b_miscCh); + fChain->SetBranchAddress("miscE", &misc.e, &b_miscE); + fChain->SetBranchAddress("miscT", &misc.t, &b_miscT); +} + +Bool_t DataDump::Notify(){ + return kTRUE; +} + +void DataDump::SlaveBegin(TTree * /*tree*/){ + // TString option = GetOption(); +} + +void DataDump::SlaveTerminate(){ +} +#endif // #ifdef DataDump_cxx diff --git a/anasen_analysis_vignesh/FitHistogramsWithTSpectrum_Sequential_Improved.C b/anasen_analysis_vignesh/FitHistogramsWithTSpectrum_Sequential_Improved.C new file mode 100644 index 0000000..1462a21 --- /dev/null +++ b/anasen_analysis_vignesh/FitHistogramsWithTSpectrum_Sequential_Improved.C @@ -0,0 +1,124 @@ +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +void FitHistogramsWithTSpectrum_Sequential_Improved() { + TFile *inputFile = new TFile("Histograms_anodes.root", "READ"); + if (!inputFile || inputFile->IsZombie()) { + std::cerr << "Error opening the input file!" << std::endl; + return; + } + + TCanvas *c1 = new TCanvas("c1", "Histogram Viewer", 800, 600); + + // Open the output ASCII file to save the centroids + std::ofstream outFile("centroids.txt"); + if (!outFile.is_open()) { + std::cerr << "Error opening output file!" << std::endl; + return; + } + outFile << "HistogramIndex\tPeakNumber\tCentroid\tAmplitude\tSigma" << std::endl; + + for (int i = 0; i < 24; ++i) { + TH1 *histogram = dynamic_cast(inputFile->Get(Form("hCathode_%d", i))); + if (!histogram) { + std::cerr << "Failed to retrieve histogram_" << i << " from the file." << std::endl; + continue; + } + + // Set range for peak search + double minX = 700; + double maxX = 25000; + histogram->GetXaxis()->SetRangeUser(minX, maxX); + + // Draw the histogram + c1->cd(); + histogram->Draw(); + + // Peak search using TSpectrum + const int maxPeaks = 5; + TSpectrum spectrumFinder(maxPeaks); + int nFound = spectrumFinder.Search(histogram, 2, "", 0.01); + + if (nFound <= 0) { + std::cerr << "No peaks found for histogram " << i << std::endl; + continue; + } + + Double_t *xPositions = spectrumFinder.GetPositionX(); + Double_t *yPositions = spectrumFinder.GetPositionY(); + std::vector> peaks; + + // Collect and sort peaks by X position + for (int j = 0; j < nFound; ++j) { + peaks.emplace_back(xPositions[j], yPositions[j]); + } + std::sort(peaks.begin(), peaks.end()); + + // Fit each peak with a Gaussian + for (int j = 0; j < peaks.size(); ++j) { + Double_t peakX = peaks[j].first; + Double_t peakY = peaks[j].second; + Double_t initialAmplitude = peakY; // Better initial guess + Double_t initialCentroid = peakX; // Centroid based on peak position + Double_t initialSigma = 60.0; + // Define Gaussian with initial parameters + TF1 *gaussFit = new TF1(Form("gauss_%d", j), "gaus", peakX - 200, peakX + 200); + //gaussFit->SetParameters(peakY, peakX, 25.0); // Initial guesses for amplitude, mean, sigma + gaussFit->SetParameters(initialAmplitude, initialCentroid, initialSigma); + // Perform fit + int fitStatus = histogram->Fit(gaussFit, "RQ+"); + if (fitStatus != 0) { + std::cerr << "Fit failed for peak " << j + 1 << " in histogram " << i << std::endl; + delete gaussFit; + continue; + } + + // Retrieve fit parameters + double amplitude = gaussFit->GetParameter(0); + double centroid = gaussFit->GetParameter(1); + double sigma = gaussFit->GetParameter(2); + double amplitudeError = gaussFit->GetParError(0); + double centroidError = gaussFit->GetParError(1); + double sigmaError = gaussFit->GetParError(2); + + // Chi-squared value + double chi2 = gaussFit->GetChisquare(); + int ndf = gaussFit->GetNDF(); + outFile << i << "\t" << j + 1 << "\t" << centroid << std::endl; + gaussFit->SetLineColor(kRed); + gaussFit->Draw("SAME"); + TText *text = new TText(); + text->SetNDC(); + text->SetTextSize(0.03); + text->SetTextColor(kRed); + //text->DrawText(0.15, 0.8 - j * 0.05, Form("Peak %d: Amp=%.2f, Mean=%.2f, Sigma=%.2f", j + 1, amplitude, centroid, sigma)); + text->DrawText(0.15, 0.8 - j * 0.05, + Form("Peak %d: Amp=%.2f±%.2f, Mean=%.2f±%.2f, Sigma=%.2f±%.2f, Chi2/NDF=%.2f", + j + 1, amplitude, amplitudeError, centroid, centroidError, sigma, sigmaError, chi2 / ndf)); + // Save results + + + // Clean up + delete gaussFit; + } + + // Update canvas for visualization + c1->Update(); + std::cout << "Press Enter to view the next histogram..." << std::endl; + c1->WaitPrimitive(); // Wait until Enter is pressed in the ROOT console + } + + // Close resources + inputFile->Close(); + outFile.close(); + delete c1; +} + diff --git a/anasen_analysis_vignesh/GainMatchQQQ.C b/anasen_analysis_vignesh/GainMatchQQQ.C new file mode 100644 index 0000000..b428da2 --- /dev/null +++ b/anasen_analysis_vignesh/GainMatchQQQ.C @@ -0,0 +1,309 @@ +#define GainMatchQQQ_cxx + +#include "GainMatchQQQ.h" +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "Armory/HistPlotter.h" +#include "TVector3.h" +#include "TGraphErrors.h" +#include "TF1.h" +#include + +TH2F *hQQQFVB; +HistPlotter *plotter; + +int padID = 0; + +TCutG *cut; +std::map, std::vector>> dataPoints; + +void GainMatchQQQ::Begin(TTree * /*tree*/) +{ + plotter = new HistPlotter("GainQQQ.root", "TFILE"); + TString option = GetOption(); + + hQQQFVB = new TH2F("hQQQFVB", "QQQ Front vs Back; Front E; Back E", 800, 0, 16000, 800, 0, 16000); + + // Load the TCutG object + TFile *cutFile = TFile::Open("qqqcorr.root"); + if (!cutFile || cutFile->IsZombie()) + { + std::cerr << "Error: Could not open qqqcorr.root" << std::endl; + return; + } + cut = dynamic_cast(cutFile->Get("qqqcorr")); + if (!cut) + { + std::cerr << "Error: Could not find TCutG named 'qqqcorr' in qqqcorr.root" << std::endl; + return; + } + cut->SetName("qqqcorr"); // Ensure the cut has the correct name +} + +Bool_t GainMatchQQQ::Process(Long64_t entry) +{ + + int ringMults[16] = {0}; + int wedgeMults[16] = {0}; + std::vector> events; + + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + + qqq.CalIndex(); + + for (int i = 0; i < qqq.multi; i++) + { + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + float eWedge = 0.0; + float eRing = 0.0; + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j]; + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i]; + } + else + continue; + ringMults[chRing]++; + wedgeMults[chWedge]++; + hQQQFVB->Fill(eWedge, eRing); + events.emplace_back(qqq.id[i], chRing, chWedge, eRing, eWedge); + plotter->Fill2D(Form("hRaw_qqq%d_ring%d_wedge%d", qqq.id[i], chRing, chWedge), 800, 0, 3000, 800, 0, 3000, eWedge, eRing, "hRawQQQ"); + // double ratio = (eWedge > 0.0) ? (eRing / eWedge) : 0.0; + // double maxslope = 1.5; + + // bool validPoint = false; + // if (ratio < maxslope && ratio > 1. / maxslope) + // { + // // Accumulate data for gain matching + // dataPoints[{qqq.id[i], chRing, chWedge}].emplace_back(eWedge, eRing); + // plotter->Fill2D("hAll_in", 4000, 0, 16000, 4000, 0, 16000, eWedge, eRing); + // validPoint = true; + // } + + // if (!validPoint) + // { + // plotter->Fill2D("hAll_out", 4000, 0, 16000, 4000, 0, 16000, eWedge, eRing); + // } + } + } + } + + for (auto tuple : events) + { + auto [id, chr, chw, er, ew] = tuple; + if (ringMults[chr] > 1 || wedgeMults[chw] > 1) + continue; // ignore multiplicity > 1 events + double ratio = (ew > 0.0) ? (er / ew) : 0.0; + double maxslope = 1.5; + + bool validPoint = false; + if (ratio < maxslope && ratio > 1. / maxslope) + { + // Accumulate data for gain matching + dataPoints[{id, chr, chw}].emplace_back(ew, er); + plotter->Fill2D("hAll_in", 4000, 0, 16000, 4000, 0, 16000, ew, er); + validPoint = true; + } + if (!validPoint) + { + plotter->Fill2D("hAll_out", 4000, 0, 16000, 4000, 0, 16000, ew, er); + } + } + + return kTRUE; +} + + +void GainMatchQQQ::Terminate() +{ + const int MAX_DET = 4; + const int MAX_RING = 16; + const int MAX_WEDGE = 16; + + // We store gains locally just for the "corrected" plot, + // but the file will output Slopes for the global minimizer. + double gainW[MAX_DET][MAX_RING][MAX_WEDGE] = {{{0}}}; + double gainR[MAX_DET][MAX_RING][MAX_WEDGE] = {{{0}}}; + bool gainValid[MAX_DET][MAX_RING][MAX_WEDGE] = {{{false}}}; + + // Output file for the Minimizer + std::ofstream outFile("qqq_GainMatch.txt"); + + // Benchmark/Debug file + std::ofstream benchFile("benchmark_diff.txt"); + benchFile << "ID Wedge Ring Chi2NDF Slope SlopeErr" << std::endl; + + if (!outFile.is_open()) { std::cerr << "Error opening output file!" << std::endl; return; } + + const int MIN_POINTS = 50; + const int MAX_ITER = 3; // Outlier rejection passes + const double CLIP_SIGMA = 2.5; // Sigma threshold for outliers + + for (const auto &kv : dataPoints) + { + auto key = kv.first; + auto [id, ring, wedge] = key; + const auto &pts = kv.second; + + if (pts.size() < (size_t)MIN_POINTS) continue; + + std::vector> current_pts = pts; + + double finalSlope = 0.0; + double finalSlopeErr = 0.0; + bool converged = false; + + // --- Iterative Fitting --- + for (int iter = 0; iter < MAX_ITER; ++iter) + { + if (current_pts.size() < (size_t)MIN_POINTS) break; + + std::vector x, y, ex, ey; + + for (const auto &p : current_pts) + { + x.push_back(p.first); // Wedge E + y.push_back(p.second); // Ring E + ex.push_back(std::sqrt(std::abs(p.first))); // Error in X (Poisson) + ey.push_back(std::sqrt(std::abs(p.second))); // Error in Y (Poisson) + + // Sanity check to avoid 0 error + if(ex.back() < 1.0) ex.back() = 1.0; + if(ey.back() < 1.0) ey.back() = 1.0; + } + + // 2. Create Graph + TGraphErrors *gr = new TGraphErrors(current_pts.size(), x.data(), y.data(), ex.data(), ey.data()); + + // 3. Fit Linear Function through Origin + TF1 *f1= new TF1("calibFit", "[0]*x", 0, 16000); + f1->SetParameter(0, 1.0); + + // "Q"=Quiet, "N"=NoDraw, "S"=ResultPtr + // We do NOT use "W" (Ignore weights), we want to use the errors we set. + int fitStatus = gr->Fit(f1, "QNS"); + + if (fitStatus != 0) { + delete gr; delete f1; + break; + } + + finalSlope = f1->GetParameter(0); + double chi2 = f1->GetChisquare(); + double ndf = f1->GetNDF(); + + // Get the statistical error on the slope + double rawErr = f1->GetParError(0); + + // SCALING ERROR: + // If Chi2/NDF > 1, the data scatters more than Poisson stats predict. + // // We inflate the error by sqrt(Chi2/NDF) to be conservative for the Minimizer. + // double redChi2 = (ndf > 0) ? (chi2 / ndf) : 1.0; + // double inflation = (redChi2 > 1.0) ? std::sqrt(redChi2) : 1.0; + + // finalSlopeErr = rawErr * inflation; + + // 4. Outlier Rejection + if (iter == MAX_ITER - 1) { + converged = true; + delete gr; delete f1; + break; + } + + // Calculate Residuals + std::vector residuals; + double sumSqResid = 0.0; + for(size_t k=0; kEval(current_pts[k].first); + double res = current_pts[k].second - val; + residuals.push_back(res); + sumSqResid += res*res; + } + // double sigma = std::sqrt(sumSqResid / current_pts.size()); + + // // Filter + // std::vector> next_pts; + // for(size_t k=0; kFill2D("hAll", 4000, 0, 16000, 4000, 0, 16000, corrWedge, corrRing); + } + } + + plotter->FlushToDisk(); +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/GainMatchQQQ.h b/anasen_analysis_vignesh/GainMatchQQQ.h new file mode 100644 index 0000000..ad06a0d --- /dev/null +++ b/anasen_analysis_vignesh/GainMatchQQQ.h @@ -0,0 +1,114 @@ +#ifndef GainMatchQQQ_h +#define GainMatchQQQ_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class GainMatchQQQ : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + + GainMatchQQQ(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~GainMatchQQQ() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(GainMatchQQQ,0); +}; + +#endif + +#ifdef GainMatchQQQ_cxx +void GainMatchQQQ::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + +} + +Bool_t GainMatchQQQ::Notify(){ + + return kTRUE; +} + +void GainMatchQQQ::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void GainMatchQQQ::SlaveTerminate(){ + +} + + +#endif // #ifdef GainMatchQQQ_cxx \ No newline at end of file diff --git a/anasen_analysis_vignesh/GainMatchSX3.C b/anasen_analysis_vignesh/GainMatchSX3.C new file mode 100644 index 0000000..dd385af --- /dev/null +++ b/anasen_analysis_vignesh/GainMatchSX3.C @@ -0,0 +1,432 @@ +#define GainMatchSX3_cxx + +#include "GainMatchSX3.h" +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "Armory/ClassSX3.h" +#include "Armory/HistPlotter.h" +#include +#include "TVector3.h" + +TH2F *hSX3FvsB; +TH2F *hSX3FvsB_g; +TH2F *hsx3IndexVE; +TH2F *hsx3IndexVE_g; +TH2F *hSX3; +TH2F *hsx3Coin; + +int padID = 0; + +SX3 sx3_contr; +TCutG *cut; +TCutG *cut1; +std::map, std::vector>> dataPoints; +std::map, int> comboCounts; + +const int MAX_DET = 24; +const int MAX_UP = 4; +const int MAX_DOWN = 4; +const int MAX_BK = 4; + +double frontGainUp[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{0}}}}; +double frontGainDown[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{0}}}}; +bool frontGainValid[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{false}}}}; +TCanvas c("canvas", "canvas", 800, 600); + +// ==== Configuration Flags ==== +const bool interactiveMode = true; // If true: show canvas + wait for user +const bool verboseFit = true; // If true: print fit summary and chi² +const bool drawCanvases = true; // If false: canvases won't be drawn at all + +// HistPlotter plotter("SX3GainMatchBack.root"); + +void GainMatchSX3::Begin(TTree * /*tree*/) +{ + TString option = GetOption(); + + hSX3FvsB = new TH2F("hSX3FvsB", "SX3 Front vs Back; Front E; Back E", 400, 0, 16000, 400, 0, 16000); + hSX3FvsB_g = new TH2F("hSX3FvsB_g", "SX3 Front vs Back; Front E; Back E", 400, 0, 16000, 400, 0, 16000); + hsx3IndexVE = new TH2F("hsx3IndexVE", "SX3 index vs Energy; sx3 index ; Energy", 24 * 12, 0, 24 * 12, 400, 0, 5000); + hsx3IndexVE_g = new TH2F("hsx3IndexVE_g", "SX3 index vs Energy; sx3 index ; Energy", 24 * 12, 0, 24 * 12, 400, 0, 5000); + hSX3 = new TH2F("hSX3", "SX3 Front v Back; Fronts; Backs", 8, 0, 8, 4, 0, 4); + + hsx3Coin = new TH2F("hsx3Coin", "SX3 Coincident", 24 * 12, 0, 24 * 12, 24 * 12, 0, 24 * 12); + + sx3_contr.ConstructGeo(); + + // Load the TCutG object + TFile *cutFile = TFile::Open("sx3cut.root"); + if (!cutFile || cutFile->IsZombie()) + { + std::cerr << "Error: Could not open sx3cut.root" << std::endl; + return; + } + cut = dynamic_cast(cutFile->Get("sx3cut")); + if (!cut) + { + std::cerr << "Error: Could not find TCutG named 'sx3cut' in sx3cut.root" << std::endl; + return; + } + cut->SetName("sx3cut"); // Ensure the cut has the correct name + + // Load the TCutG object + TFile *cutFile1 = TFile::Open("UvD.root"); + bool cut1Loaded = (cut1 != nullptr); + cut1 = dynamic_cast(cutFile1->Get("UvD")); + if (!cut1) + { + std::cerr << "Error: Could not find TCutG named 'UvD' in UvD.root" << std::endl; + return; + } + cut1->SetName("UvD"); + + // plotter.ReadCuts("cuts.txt"); + + std::string filename = "sx3_GainMatchfront.txt"; + // std::string filename = "sx3_GainMatchfront.txt"; + + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + return; + } + + int id, bk, u, d; + double gainup, gaindown; + while (infile >> id >> bk >> u >> d >> gainup >> gaindown) + { + frontGainUp[id][bk][u][d] = gainup; + frontGainDown[id][bk][u][d] = gaindown; + frontGainValid[id][bk][u][d] = true; + if(frontGainValid[id][bk][u][d]) { + // std::cout << "Loaded front gain for Det" << id << " Bk" << bk << " U" << u << " D" << d + // << ": Up=" << gainup << ", Down=" << gaindown << std::endl; + } + else { + std::cout << "No valid front gain for Det" << id << " Bk" << bk << " U" << u << " D" << d << std::endl; + } + } +} + +Bool_t GainMatchSX3::Process(Long64_t entry) +{ + + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + std::vector> ID; + for (int i = 0; i < sx3.multi; i++) + { + + // for (int j = i + 1; j < sx3.multi; j++) + // { + // if (sx3.id[i] == 3) + // hsx3Coin->Fill(sx3.index[i], sx3.index[j]); + // } + if (sx3.e[i] > 100) + { + ID.push_back(std::pair(sx3.id[i], i)); + hsx3IndexVE->Fill(sx3.index[i], sx3.e[i]); + } + } + + if (ID.size() > 0) + { + std::sort(ID.begin(), ID.end(), [](const std::pair &a, const std::pair &b) + { return a.first < b.first; }); + + // start with the first entry in the sorted array: channels that belong to the same detector are together in sequenmce + std::vector> sx3ID; + sx3ID.push_back(ID[0]); + bool found = false; + + for (size_t i = 1; i < ID.size(); i++) + { // Check if id of i belongs to the same detector and then add it to the detector ID vector + if (ID[i].first == sx3ID.back().first) + { // count the nunmber of hits that belong to the same detector + sx3ID.push_back(ID[i]); + + if (sx3ID.size() >= 3) + { + found = true; + } + } + else + { // the next event does not belong to the same detector, abandon the first event and continue with the next one + if (!found) + { + sx3ID.clear(); + sx3ID.push_back(ID[i]); + } + } + } + + if (found) + { + int sx3ChUp = -1, sx3ChDn = -1, sx3ChBk = -1; + float sx3EUp = 0.0, sx3EDn = 0.0, sx3EBk = 0.0; + + // Build the correlated set once + for (size_t i = 0; i < sx3ID.size(); i++) + { + if (sx3.e[i] > 100) + { + int index = sx3ID[i].second; + if (sx3.ch[index] < 8) + { + if (sx3.ch[index] % 2 == 0) + { + sx3ChDn = sx3.ch[index]; + sx3EDn = sx3.e[index]; + // + } + else + { + sx3ChUp = sx3.ch[index]; + sx3EUp = sx3.e[index]; + } + } + else + { + sx3ChBk = sx3.ch[index] - 8; + sx3EBk = sx3.e[index]; + } + } + + } + // Only if we found all three channels do we proceed + if (sx3ChUp >= 0 && sx3ChDn >= 0 && sx3ChBk >= 0) + { + // Fill once per correlated set + hSX3->Fill(sx3ChDn + 4, sx3ChBk); + hSX3->Fill(sx3ChUp, sx3ChBk); + hSX3FvsB->Fill(sx3EUp + sx3EDn, sx3EBk); + + if (frontGainValid[sx3ID[0].first][sx3ChBk][sx3ChUp / 2][sx3ChDn / 2]) + { + sx3EUp *= frontGainUp[sx3ID[0].first][sx3ChBk][sx3ChUp / 2][sx3ChDn / 2]; + sx3EDn *= frontGainDown[sx3ID[0].first][sx3ChBk][sx3ChUp / 2][sx3ChDn / 2]; + } + else + { + // printf("No front gain for Det%d Bk%d U%d D%d\n", sx3ID[0].first, sx3ChBk, sx3ChUp / 2, sx3ChDn / 2); + sx3EUp = sx3EDn = 0.; + } + // plotter.Fill2D("hSX3F", 400, 0, 16000, 400, 0, 16000, sx3EUp + sx3EDn, sx3EBk); + + // Pick detector ID from one of the correlated hits (all same detector) + int detID = sx3ID[0].first; + + TString histName = Form("hSX3FVB_id%d_U%d_D%d_B%d", detID, sx3ChUp, sx3ChDn, sx3ChBk); + TString histName1 = Form("UnCorr_id%d_U%d-D%dvsB%d", detID, sx3ChUp, sx3ChDn, sx3ChBk); + + TH2F *hist2d = (TH2F *)gDirectory->Get(histName); + TH2F *hist2d1 = (TH2F *)gDirectory->Get(histName1); + if (!hist2d) + { + hist2d = new TH2F(histName, histName, + 400, 0, 16000, 400, 0, 16000); + } + if (!hist2d1) + { + hist2d1 = new TH2F(histName1, histName1, + 800, -1, 1, 800, 0, 4000); + } + + if (sx3EBk > 100 || sx3EUp > 100 || sx3EDn > 100) + { + hSX3FvsB_g->Fill(sx3EUp + sx3EDn, sx3EBk); + + // Use the correlated triplet directly + dataPoints[{detID, sx3ChBk, sx3ChUp, sx3ChDn}] + .emplace_back(sx3EBk, sx3EUp, sx3EDn); + } + + hist2d->Fill(sx3EUp + sx3EDn, sx3EBk); + hist2d1->Fill((sx3EUp - sx3EDn) / (sx3EUp + sx3EDn), sx3EBk); + } + } + } + + return kTRUE; +} + +const double GAIN_ACCEPTANCE_THRESHOLD = 0.3; +void GainMatchSX3::Terminate() +{ + double backSlope[MAX_DET][MAX_BK] = {{0}}; + bool backSlopeValid[MAX_DET][MAX_BK] = {{false}}; + + std::ofstream outFile("sx3_BackGains0.txt"); + if (!outFile.is_open()) + { + std::cerr << "Error opening sx3_BackGains.txt for writing!" << std::endl; + return; + } + + // === Gain fit: (Up+Dn) vs Back, grouped by [id][bk] === + for (int id = 0; id < MAX_DET; id++) + { + for (int bk = 0; bk < MAX_BK; bk++) + { + std::vector bkE, udE; + + // Collect all (Up+Dn, Back) for this id,bk + for (const auto &kv : dataPoints) + { + auto [cid, cbk, u, d] = kv.first; + if (cid != id || cbk != bk) + continue; + + for (const auto &pr : kv.second) + { + double eBk, eUp, eDn; + std::tie(eBk, eUp, eDn) = pr; + if ((eBk < 100) || (eUp < 100) || (eDn < 100)) + continue; + + bkE.push_back(eBk); + udE.push_back(eUp + eDn); + } + } + + if (bkE.size() < 5) + continue; // not enough statistics + + // Build graph with errors + const double fixedError = 0.0; // ADC channels + std::vector exVals(udE.size(), 0.0); // no x error + std::vector eyVals(udE.size(), fixedError); // constant y error + + TGraphErrors g(udE.size(), udE.data(), bkE.data(), + exVals.data(), eyVals.data()); + + TF1 f("f", "[0]*x", 0, 16000); + // f.SetParameter(0, 1.0); // initial slope + + if (drawCanvases) + { + g.SetTitle(Form("Detector %d Back %d: (Up+Dn) vs Back", id, bk)); + g.SetMarkerStyle(20); + g.SetMarkerColor(kBlue); + g.Draw("AP"); + + g.Fit(&f, interactiveMode ? "Q" : "QNR"); + + if (verboseFit) + { + double chi2 = f.GetChisquare(); + int ndf = f.GetNDF(); + double reducedChi2 = (ndf != 0) ? chi2 / ndf : -1; + + std::cout << Form("Det%d Back%d → Slope: %.4f | χ²/ndf = %.2f/%d = %.2f", + id, bk, f.GetParameter(0), chi2, ndf, reducedChi2) + << std::endl; + } + + if (interactiveMode) + { + c.Update(); + gPad->WaitPrimitive(); + } + else + { + c.Close(); + } + } + else + { + g.Fit(&f, "QNR"); + } + + double slope = 1 / f.GetParameter(0); + if (std::abs(slope - 1.0) < 0.3) // sanity check + { + backSlope[id][bk] = slope; + backSlopeValid[id][bk] = true; + outFile << id << " " << bk << " " << slope << "\n"; + printf("Back slope Det%d Bk%d → %.4f\n", id, bk, slope); + } + else + { + std::cerr << "Warning: Bad slope for Det" << id << " Bk" << bk + << " slope=" << slope << std::endl; + } + } + } + + outFile.close(); + std::cout << "Back gain matching complete." << std::endl; + + // === Create histograms === + TH2F *hFVB = new TH2F("hFVB", "Corrected Up+Dn vs Corrected Back;Up+Dn E;Corrected Back E", + 600, 0, 16000, 600, 0, 16000); + TH2F *hAsym = new TH2F("hAsym", "Up vs Dn divide corrected back;Up/Back E;Dn/Back E", + 400, 0.0, 1.0, 400, 0.0, 1.0); + TH2F *hAsymUnorm = new TH2F("hAsymUnorm", "Up vs Dn;Up E;Dn E", + 800, 0.0, 4000.0, 800, 0.0, 4000.0); + + // Fill histograms using corrected back energies + for (const auto &kv : dataPoints) + { + auto [id, bk, u, d] = kv.first; + if (!backSlopeValid[id][bk]) + continue; + + double slope = backSlope[id][bk]; + + for (const auto &pr : kv.second) + { + double eBk, eUp, eDn; + std::tie(eBk, eUp, eDn) = pr; + + double updn = eUp + eDn; + if (updn == 0 || eBk == 0) + continue; + + double correctedBack = eBk * slope; + double asym = (eUp - eDn) / updn; + + hFVB->Fill(updn, correctedBack); + hAsym->Fill(eUp / correctedBack, eDn / correctedBack); + hAsymUnorm->Fill(eUp, eDn); + TString histNamex = Form("CorrBack_id%d_U%d-D%dvsB%d", id, u, d, bk); + + TH2F *hist2dx = (TH2F *)gDirectory->Get(histNamex); + if (!hist2dx) + { + hist2dx = new TH2F(histNamex, histNamex, + 800, -1, 1, 800, 0, 4000); + } + + hist2dx->Fill((eUp - eDn) / (eUp + eDn), correctedBack); + } + } + // plotter.FlushToDisk(); +} diff --git a/anasen_analysis_vignesh/GainMatchSX3.h b/anasen_analysis_vignesh/GainMatchSX3.h new file mode 100644 index 0000000..5088a32 --- /dev/null +++ b/anasen_analysis_vignesh/GainMatchSX3.h @@ -0,0 +1,114 @@ +#ifndef GainMatchSX3_h +#define GainMatchSX3_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class GainMatchSX3 : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + + GainMatchSX3(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~GainMatchSX3() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(GainMatchSX3,0); +}; + +#endif + +#ifdef GainMatchSX3_cxx +void GainMatchSX3::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + +} + +Bool_t GainMatchSX3::Notify(){ + + return kTRUE; +} + +void GainMatchSX3::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void GainMatchSX3::SlaveTerminate(){ + +} + + +#endif // #ifdef GainMatchSX3_cxx \ No newline at end of file diff --git a/anasen_analysis_vignesh/GainMatchSX3Front.C b/anasen_analysis_vignesh/GainMatchSX3Front.C new file mode 100644 index 0000000..9166c2c --- /dev/null +++ b/anasen_analysis_vignesh/GainMatchSX3Front.C @@ -0,0 +1,420 @@ +#define GainMatchSX3Front_cxx + +#include "GainMatchSX3Front.h" +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "Armory/ClassSX3.h" +#include "TGraphErrors.h" +#include "TMultiDimFit.h" + +#include "TVector3.h" + +TH2F *hSX3FvsB; +TH2F *hSX3FvsB_g; +TH2F *hsx3IndexVE; +TH2F *hsx3IndexVE_g; +TH2F *hSX3; +TH2F *hsx3Coin; + +int padID = 0; + +SX3 sx3_contr; +TCutG *cut; +TCutG *cut1; +std::map, std::vector>> dataPoints; +TCanvas c(Form("canvas"), "Fit", 800, 600); + +// Gain arrays + +const int MAX_DET = 24; +const int MAX_UP = 4; +const int MAX_DOWN = 4; +const int MAX_BK = 4; +double backGain[MAX_DET][MAX_BK] = {{0}}; +bool backGainValid[MAX_DET][MAX_BK] = {{false}}; +double frontGain[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{0}}}}; +bool frontGainValid[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{false}}}}; +double uvdslope[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{0}}}}; +// ==== Configuration Flags ==== +const bool interactiveMode = true; // If true: show canvas + wait for user +const bool verboseFit = true; // If true: print fit summary and chi² +const bool drawCanvases = true; // If false: canvases won't be drawn at all + +void GainMatchSX3Front::Begin(TTree * /*tree*/) +{ + TString option = GetOption(); + + hSX3FvsB = new TH2F("hSX3FvsB", "SX3 Front vs Back; Front E; Back E", 800, 0, 16000, 800, 0, 16000); + hSX3FvsB_g = new TH2F("hSX3FvsB_g", "SX3 Front vs Back; Front E; Back E", 800, 0, 16000, 800, 0, 16000); + hsx3IndexVE = new TH2F("hsx3IndexVE", "SX3 index vs Energy; sx3 index ; Energy", 24 * 12, 0, 24 * 12, 400, 0, 5000); + hsx3IndexVE_g = new TH2F("hsx3IndexVE_g", "SX3 index vs Energy; sx3 index ; Energy", 24 * 12, 0, 24 * 12, 400, 0, 5000); + hSX3 = new TH2F("hSX3", "SX3 Front v Back; Fronts; Backs", 8, 0, 8, 4, 0, 4); + + hsx3Coin = new TH2F("hsx3Coin", "SX3 Coincident", 24 * 12, 0, 24 * 12, 24 * 12, 0, 24 * 12); + + sx3_contr.ConstructGeo(); + + // Load the TCutG object + TFile *cutFile = TFile::Open("sx3cut.root"); + bool cutLoaded = (cut != nullptr); + cut = dynamic_cast(cutFile->Get("sx3cut")); + if (!cut) + { + std::cerr << "Error: Could not find TCutG named 'sx3cut' in sx3cut.root" << std::endl; + return; + } + cut->SetName("sx3cut"); // Ensure the cut has the correct name + + // Load the TCutG object + TFile *cutFile1 = TFile::Open("UvD.root"); + bool cut1Loaded = (cut1 != nullptr); + cut1 = dynamic_cast(cutFile1->Get("UvD")); + if (!cut1) + { + std::cerr << "Error: Could not find TCutG named 'UvD' in UvD.root" << std::endl; + return; + } + cut1->SetName("UvD"); + + std::string filename = "sx3_BackGains.txt"; + + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + return; + } + + int id, bk; + double gain; + while (infile >> id >> bk >> gain) + { + backGain[id][bk] = gain; + if (backGain[id][bk] > 0) + backGainValid[id][bk] = true; + else + backGainValid[id][bk] = false; + } + + SX3 sx3_contr; +} + +Bool_t GainMatchSX3Front::Process(Long64_t entry) +{ + + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + + sx3.CalIndex(); + + std::vector> ID; + for (int i = 0; i < sx3.multi; i++) + { + + for (int j = i + 1; j < sx3.multi; j++) + { + // if (sx3.id[i] == 3) + hsx3Coin->Fill(sx3.index[i], sx3.index[j]); + } + if (sx3.e[i] > 100) + { + ID.push_back(std::pair(sx3.id[i], i)); + hsx3IndexVE->Fill(sx3.index[i], sx3.e[i]); + } + } + + if (ID.size() > 0) + { + std::sort(ID.begin(), ID.end(), [](const std::pair &a, const std::pair &b) + { return a.first < b.first; }); + + // start with the first entry in the sorted array: channels that belong to the same detector are together in sequenmce + std::vector> sx3ID; + sx3ID.push_back(ID[0]); + bool found = false; + + for (size_t i = 1; i < ID.size(); i++) + { // Check if id of i belongs to the same detector and then add it to the detector ID vector + if (ID[i].first == sx3ID.back().first) + { // count the nunmber of hits that belong to the same detector + sx3ID.push_back(ID[i]); + + if (sx3ID.size() >= 3) + { + found = true; + } + } + else + { // the next event does not belong to the same detector, abandon the first event and continue with the next one + if (!found) + { + sx3ID.clear(); + sx3ID.push_back(ID[i]); + } + } + } + + if (found) + { + int sx3ChUp = -1, sx3ChDn = -1, sx3ChBk = -1; + float sx3EUp = 0.0, sx3EDn = 0.0, sx3EBk = 0.0; + + for (size_t i = 0; i < sx3ID.size(); i++) + { + int index = sx3ID[i].second; + // Check the channel number and assign it to the appropriate channel type + if (sx3.ch[index] < 8) + { + if (sx3.ch[index] % 2 == 0) + { + sx3ChDn = sx3.ch[index] / 2; + sx3EDn = sx3.e[index]; + } + else + { + sx3ChUp = sx3.ch[index] / 2; + sx3EUp = sx3.e[index]; + } + } + else + { + sx3ChBk = sx3.ch[index] - 8; + // if (sx3ChBk == 2) + // printf("Found back channel Det %d Back %d \n", sx3.id[index], sx3ChBk); + sx3EBk = sx3.e[index]; + } + } + + for (int i = 0; i < sx3.multi; i++) + { + // If we have a valid front and back channel, fill the histograms + hSX3->Fill(sx3ChDn + 4, sx3ChBk); + hSX3->Fill(sx3ChUp, sx3ChBk); + + // Fill the histogram for the front vs back + hSX3FvsB->Fill(sx3EUp + sx3EDn, sx3EBk); + + if (sx3.e[i] > 100 && sx3.id[i] == 3) + { + // back gain correction + + // Fill the histogram for the front vs back with gain correction + // hSX3FvsB_g->Fill(sx3EUp + sx3EDn, sx3EBk); + // // Fill the index vs energy histogram + // hsx3IndexVE_g->Fill(sx3.index[i], sx3.e[i]); + // } + // { + TString histName = Form("hSX3FVB_id%d_U%d_D%d_B%d", sx3.id[i], sx3ChUp, sx3ChDn, sx3ChBk); + TH2F *hist2d = (TH2F *)gDirectory->Get(histName); + if (!hist2d) + { + hist2d = new TH2F(histName, Form("hSX3FVB_id%d_U%d_D%d_B%d", sx3.id[i], sx3ChUp, sx3ChDn, sx3ChBk), 400, 0, 16000, 400, 0, 16000); + } + + // if (sx3ChBk == 2) + // printf("Found back channel Det %d Back %d \n", sx3.id[i], sx3ChBk); + hsx3IndexVE_g->Fill(sx3.index[i], sx3.e[i]); + hSX3FvsB_g->Fill(sx3EUp + sx3EDn, sx3EBk); + + hist2d->Fill(sx3EUp + sx3EDn, sx3EBk); + + if (cut && cut->IsInside(sx3EUp + sx3EDn, sx3EBk) && cut1 && cut1->IsInside(sx3EUp / sx3EBk, sx3EDn / sx3EBk)) + { + + if (backGainValid[sx3.id[i]][sx3ChBk]) + { + sx3EBk *= backGain[sx3.id[i]][sx3ChBk]; + } + // Accumulate data for gain matching + dataPoints[{sx3.id[i], sx3ChBk, sx3ChUp, sx3ChDn}].emplace_back(sx3EBk, sx3EUp, sx3EDn); + } + } + } + } + } + + return kTRUE; +} + +void GainMatchSX3Front::Terminate() +{ + + std::map, TVectorD> fitCoefficients; + + // === Gain matching === + + std::ofstream outFile("sx3_GainMatchfront.txt"); + if (!outFile.is_open()) + { + std::cerr << "Error opening output file!" << std::endl; + return; + } + + TH2F *hUvD = new TH2F("hUvD", " UvD; Up/CorrBack; Down/CorrBack", 600, 0, 1, 600, 0, 1); + + for (const auto &kv : dataPoints) + { + auto [id, bk, u, d] = kv.first; + const auto &pts = kv.second; + + if (pts.size() < 50) + continue; + + std::vector uE, dE, udE, corrBkE; + + for (const auto &pr : pts) + { + double eBkCorr, eUp, eDn; + std::tie(eBkCorr, eUp, eDn) = pr; + if ((eBkCorr < 100) || (eUp < 100) || (eDn < 100)) + continue; // Skip if any energy is zero + uE.push_back(eUp / eBkCorr); + dE.push_back(eDn / eBkCorr); + udE.push_back(eUp + eDn); + corrBkE.push_back(eBkCorr); + hUvD->Fill(eUp / eBkCorr, eDn / eBkCorr); + } + if (uE.size() < 5 || dE.size() < 5 || corrBkE.size() < 5) + continue; // Ensure we have enough points for fitting + // TGraph g(udE.size(), udE.data(), corrBkE.data()); + + // TF1 f("f", "[0]*x", 0, 20000); + // f.SetParameter(0, 1.0); // Initial guess for the gain + // g.Fit(&f, "R"); + + const double fixedError = 0.0; // in ADC channels + + std::vector xVals, yVals, exVals, eyVals; + + // Build data with fixed error + for (size_t i = 0; i < udE.size(); ++i) + { + double x = uE[i]; // front energy + double y = dE[i]; // back energy + + xVals.push_back(x); + yVals.push_back(y); + exVals.push_back(fixedError); // error in up energy + eyVals.push_back(0.); // error in down energy + } + + // Build TGraphErrors with errors + TGraphErrors g(xVals.size(), xVals.data(), yVals.data(), exVals.data(), eyVals.data()); + + TF1 f("f", "[0]*x+[1]", 0, 16000); + f.SetParameter(0, -1.0); // Initial guess + + if (drawCanvases) + { + g.SetTitle(Form("Detector %d: U%d D%d B%d", id, u, d, bk)); + g.SetMarkerStyle(20); + g.SetMarkerColor(kBlue); + g.Draw("AP"); + + g.Fit(&f, interactiveMode ? "Q" : "QNR"); // 'R' avoids refit, 'N' skips drawing + + if (verboseFit) + { + double chi2 = f.GetChisquare(); + int ndf = f.GetNDF(); + double reducedChi2 = (ndf != 0) ? chi2 / ndf : -1; + + std::cout << Form("Det%d U%d D%d B%d → Gain: %.4f | χ²/ndf = %.2f/%d = %.2f", + id, u, d, bk, f.GetParameter(0), chi2, ndf, reducedChi2) + << std::endl; + } + + if (interactiveMode) + { + c.Update(); + gPad->WaitPrimitive(); + } + else + { + c.Close(); // Optionally avoid clutter in batch + } + } + else + { + g.Fit(&f, "QNR"); + } + + double slope = f.GetParameter(0); + double intercept = f.GetParameter(1); + + // printf("Front gain Det%d Back%d Up%dDn%d → %.4f\n", id, bk, u, d, frontGain[id][bk][u][d]); + if (std::abs(slope + 1.0) < 0.3) // sanity check + { + frontGain[id][bk][u][d] = slope; + + frontGainValid[id][bk][u][d] = true; + outFile << id << " " << bk << " " << u << " " << d << " " << TMath::Abs(slope)/intercept << " " << 1.0/intercept << std::endl; + printf("Back slope Det%d Bk%d → %.4f\n", id, bk, slope); + } + else + { + std::cerr << "Warning: Bad slope for Det" << id << " Bk" << bk + << " slope=" << f.GetParameter(0) << std::endl; + } + } + + outFile.close(); + std::cout << "Gain matching complete." << std::endl; + + // === Stage 3: Create corrected histogram === + TH2F *hCorrectedFvB = new TH2F("hCorrectedFvB", "Corrected;Corrected Front Sum;Corrected Back", 800, 0, 8000, 800, 0, 8000); + TH2F *hCorrectedUvD = new TH2F("hCorrectedUvD", "Corrected UvD; UvD Up; UvD Down", 600, 0, 1, 600, 0, 1); + + for (const auto &kv : dataPoints) + { + + auto [id, bk, u, d] = kv.first; + double front; + if (frontGainValid[id][bk][u][d]) + front = frontGain[id][bk][u][d]; + else + continue; + for (const auto &pr : kv.second) + { + double eBk, eUp, eDn; + std::tie(eBk, eUp, eDn) = pr; + double corrUp = eUp * front; + // double corrDn = eDn * front; + + hCorrectedFvB->Fill(corrUp + eDn, eBk); + hCorrectedUvD->Fill(corrUp / eBk, eDn / eBk); + } + } + + // // === Final canvas === + // gStyle->SetOptStat(1110); + // TCanvas *c1 = new TCanvas("c1", "Gain Correction Results", 1200, 600); + // c1->Divide(2, 1); + + // c1->cd(1); + // hSX3FvsB_g->SetTitle("Before Correction (Gated)"); + // hSX3FvsB_g->GetXaxis()->SetTitle("Measured Front Sum (E_Up + E_Dn)"); + // hSX3FvsB_g->GetYaxis()->SetTitle("Measured Back E"); + // hSX3FvsB_g->Draw("colz"); + + // c1->cd(2); + // hCorrectedFvB->SetTitle("After Correction"); + // hCorrectedFvB->Draw("colz"); + // TF1 *diag = new TF1("diag", "x", 0, 40000); + // diag->SetLineColor(kRed); + // diag->SetLineWidth(2); + // diag->Draw("same"); + + std::cout << "Terminate() completed successfully." << std::endl; +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/GainMatchSX3Front.h b/anasen_analysis_vignesh/GainMatchSX3Front.h new file mode 100644 index 0000000..47aef61 --- /dev/null +++ b/anasen_analysis_vignesh/GainMatchSX3Front.h @@ -0,0 +1,104 @@ +#ifndef GainMatchSX3Front_h +#define GainMatchSX3Front_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class GainMatchSX3Front : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + + GainMatchSX3Front(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~GainMatchSX3Front() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(GainMatchSX3Front,0); +}; + +#endif + +#ifdef GainMatchSX3Front_cxx +void GainMatchSX3Front::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + +} + +Bool_t GainMatchSX3Front::Notify(){ + + return kTRUE; +} + +void GainMatchSX3Front::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void GainMatchSX3Front::SlaveTerminate(){ + +} + + +#endif // #ifdef GainMatchSX3Front_cxx \ No newline at end of file diff --git a/anasen_analysis_vignesh/GainMatchSX3Front1.C b/anasen_analysis_vignesh/GainMatchSX3Front1.C new file mode 100644 index 0000000..28ac0e2 --- /dev/null +++ b/anasen_analysis_vignesh/GainMatchSX3Front1.C @@ -0,0 +1,245 @@ +#define GainMatchSX3_cxx + +#include "GainMatchSX3.h" +#include "Armory/ClassSX3.h" +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +// Constants +const int MAX_DET = 24; +const int MAX_BK = 4; +const int MAX_UP = 4; +const int MAX_DOWN = 4; + +// Gain arrays +double backGain[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{0}}}}; +bool backGainValid[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{false}}}}; + +double frontGain[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{0}}}}; +bool frontGainValid[MAX_DET][MAX_BK][MAX_UP][MAX_DOWN] = {{{{false}}}}; + +// Data container +std::map, std::vector>> dataPoints; + +// Load back gains +void LoadBackGains(const std::string &filename) +{ + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + return; + } + + int id, bk, u, d; + double gain; + while (infile >> id >> bk >> u >> d >> gain) + { + backGain[id][bk][u][d] = gain; + backGainValid[id][bk][u][d] = true; + } + + infile.close(); + std::cout << "Loaded back gains from " << filename << std::endl; + SX3 sx3_contr; +} + +// Front gain matching function +Bool_t GainMatchSX3::Process(Long64_t entry) +{ + // Link SX3 branches + + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + + sx3.CalIndex(); + + Long64_t nentries = tree->GetEntries(Long64_t entry); + std::cout << "Total entries: " << nentries << std::endl; + + TH2F *hBefore = new TH2F("hBefore", "Before Correction;E_Up+E_Dn;Back Energy", 400, 0, 40000, 400, 0, 40000); + TH2F *hAfter = new TH2F("hAfter", "After Correction;E_Up+E_Dn;Corrected Back Energy", 400, 0, 40000, 400, 0, 40000); + + for (Long64_t entry = 0; entry < nentries; ++entry) + { + tree->GetEntry(entry); + sx3.CalIndex(); + + std::vector> ID; + + for (int i = 0; i < sx3.multi; i++) + { + if (sx3.e[i] > 100) + { + ID.push_back({sx3.id[i], i}); + } + } + + if (ID.empty()) + continue; + + // Sort by id + std::sort(ID.begin(), ID.end(), [](auto &a, auto &b) { return a.first < b.first; }); + + std::vector> sx3ID; + sx3ID.push_back(ID[0]); + bool found = false; + + for (size_t i = 1; i < ID.size(); i++) + { + if (ID[i].first == sx3ID.back().first) + { + sx3ID.push_back(ID[i]); + if (sx3ID.size() >= 3) + found = true; + } + else if (!found) + { + sx3ID.clear(); + sx3ID.push_back(ID[i]); + } + } + + if (!found) + continue; + + int sx3ChUp = -1, sx3ChDn = -1, sx3ChBk = -1; + float sx3EUp = 0.0, sx3EDn = 0.0, sx3EBk = 0.0; + int sx3id = sx3ID[0].first; + + for (auto &[id, idx] : sx3ID) + { + if (sx3.ch[idx] < 8) + { + if (sx3.ch[idx] % 2 == 0) + { + sx3ChDn = sx3.ch[idx] / 2; + sx3EDn = sx3.e[idx]; + } + else + { + sx3ChUp = sx3.ch[idx] / 2; + sx3EUp = sx3.e[idx]; + } + } + else + { + sx3ChBk = sx3.ch[idx] - 8; + sx3EBk = sx3.e[idx]; + } + } + + if (sx3ChUp < 0 || sx3ChDn < 0 || sx3ChBk < 0) + continue; + + if (!backGainValid[sx3id][sx3ChBk][sx3ChUp][sx3ChDn]) + continue; + + double corrBk = sx3EBk * backGain[sx3id][sx3ChBk][sx3ChUp][sx3ChDn]; + + hBefore->Fill(sx3EUp + sx3EDn, sx3EBk); + hAfter->Fill(sx3EUp + sx3EDn, corrBk); + + dataPoints[{sx3id, sx3ChBk, sx3ChUp, sx3ChDn}].emplace_back(corrBk, sx3EUp, sx3EDn); + } + + // === Fit front gains === + std::ofstream outFile("sx3_GainMatchfront.txt"); + if (!outFile.is_open()) + { + std::cerr << "Error opening sx3_GainMatchfront.txt!" << std::endl; + return; + } + + for (const auto &kv : dataPoints) + { + auto [id, bk, u, d] = kv.first; + const auto &pts = kv.second; + + if (pts.size() < 5) + continue; + + std::vector udE, corrBkE; + + for (const auto &pr : pts) + { + double eBkCorr, eUp, eDn; + std::tie(eBkCorr, eUp, eDn) = pr; + udE.push_back(eUp + eDn); + corrBkE.push_back(eBkCorr); + } + + TGraph g(udE.size(), udE.data(), corrBkE.data()); + TF1 f("f", "[0]*x", 0, 40000); + g.Fit(&f, "QNR"); + + frontGain[id][bk][u][d] = f.GetParameter(0); + frontGainValid[id][bk][u][d] = true; + + outFile << id << " " << bk << " " << u << " " << d << " " << frontGain[id][bk][u][d] << std::endl; + printf("Front gain Det%d Back%d Up%dDn%d → %.4f\n", id, bk, u, d, frontGain[id][bk][u][d]); + } + + outFile.close(); + std::cout << "Front gain matching complete." << std::endl; + + // === Draw diagnostic plots === + gStyle->SetOptStat(1110); + TCanvas *c = new TCanvas("c", "Gain Matching Diagnostics", 1200, 600); + c->Divide(2, 1); + + c->cd(1); + hBefore->Draw("colz"); + TF1 *diag1 = new TF1("diag1", "x", 0, 40000); + diag1->SetLineColor(kRed); + diag1->Draw("same"); + + c->cd(2); + hAfter->Draw("colz"); + TF1 *diag2 = new TF1("diag2", "x", 0, 40000); + diag2->SetLineColor(kRed); + diag2->Draw("same"); +} + +int main(int argc, char **argv) +{ + TApplication app("app", &argc, argv); + + // Load back gains + LoadBackGains("sx3_GainMatchback.txt"); + + // Open tree + TFile *f = TFile::Open("input_tree.root"); // <<< Change file name + if (!f || f->IsZombie()) + { + std::cerr << "Cannot open input_tree.root!" << std::endl; + return 1; + } + TTree *tree = (TTree *)f->Get("tree"); + if (!tree) + { + std::cerr << "Tree not found!" << std::endl; + return 1; + } + + // Run front gain matching + GainMatchSX3(tree); + + app.Run(); + return 0; +} diff --git a/anasen_analysis_vignesh/MakeVertex.C b/anasen_analysis_vignesh/MakeVertex.C new file mode 100644 index 0000000..0f576e1 --- /dev/null +++ b/anasen_analysis_vignesh/MakeVertex.C @@ -0,0 +1,1470 @@ +#define MakeVertex_cxx + +Int_t colors[40] = { + kBlack, kRed, kGreen, kBlue, kYellow, kMagenta, kCyan, kOrange, + kSpring, kTeal, kAzure, kViolet, kPink, kGray, kWhite, + kRed+2, kGreen+2, kBlue+2, kYellow+2, kMagenta+2, kCyan+2, kOrange+2, + kSpring+2, kTeal+2, kAzure+2, kViolet+2, kPink+2, + kRed-7, kGreen-7, kBlue-7, kYellow-7, kMagenta-7, kCyan-7, kOrange-7, + kSpring-7, kTeal-7, kAzure-7, kViolet-7, kPink-7, kGray+2 +}; + +#include "MakeVertex.h" +#include "Armory/ClassPW.h" +#include "Armory/HistPlotter.h" +#include "Armory/SX3Geom.h" +#include "scratch/sx3z_vs_phiz/testmodel.h" +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include +#include +#include +#include +#include +#include +#include + +bool realtime = true; +double source_vertex = 53; //53 +const double qqq_z = 100.0; +const double anode_gain = 1.5146e-5; //channels --> MeV +std::string dataset; + +TF1 pcfix_func("func",model_invert,-200,200); +TApplication *app=NULL; +TH1F *hha=NULL,*hhc=NULL; +TH3D *frame=NULL; +TCanvas *can1=NULL,*can2=NULL; + +TPolyLine3D *pla[24]={NULL}; +TPolyLine3D *plc[24]={NULL}; +TPolyLine3D *qqqw[16][4]={NULL}; +TPolyLine3D *trajectory=NULL; +TGraph2D *qqqg=NULL, *crossoverg=NULL, *guessg=NULL; + +double z_to_crossover_rho(double z) { + return 9.20645e-5*z*z + 34.1973; +} + +double z_to_crossover_rho_cathode(double z) { + return 9.20645e-5*z*z + 34.1973; +} + +// Global instances +PW pw_contr; +PW pwinstance; +TVector3 hitPos; +double qqqenergy, qqqtimestamp; +class Event { +public: + Event(TVector3 p, double e1, double e2, double t1, double t2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2) {} + Event(TVector3 p, double e1, double e2, double t1, double t2, int c1, int c2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2), ch1(c1), ch2(c2) {} + //Event(TVector3 p, double e1, double e2, double t1, double t2, int c1, int c2, int m1, int m2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2), ch1(c1), ch2(c2), multi1(m1), multi2(m2) {} + + TVector3 pos; + int ch1=-1; //int(ch1/16) gives qqq id, ch1%16 gives ring# + int ch2=-1; //int(ch2/16) gives qqq id, ch2%16 gives wedge# + double Energy1=-1; //Front for QQQ, Anode for PC + double Energy2=-1; //Back for QQQ, Cathode for PC + double Time1=-1; + double Time2=-1; + + //misc elements; + int multi1=-1, multi2=-1; +}; + +// Calibration globals +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; + +double sx3BackGain[24][4][4] = {{{1.}}}; +double sx3FrontGain[24][4] = {{1.}}; +double sx3FrontOffset[24][4] = {{0.}}; +double sx3RightGain[24][4] = {{1.}}; + +// PC Arrays +double pcSlope[48]; +double pcIntercept[48]; + +HistPlotter *plotter; + +bool HitNonZero; +bool sx3ecut; +bool qqqEcut; + +void MakeVertex::Begin(TTree * /*tree*/) +{ + pcfix_func.SetNpx(100000); + TString option = GetOption(); + if(option!="") + plotter = new HistPlotter(option.Data(),"TFILE"); + else + plotter = new HistPlotter("Analyzer_SX3.root", "TFILE"); + + pw_contr.ConstructGeo(); + pwinstance.ConstructGeo(); + if(gROOT->IsBatch()) realtime=false; + + // --------------------------------------------------------- + // 1. CRITICAL FIX: Initialize PC Arrays to Default (Raw) + // --------------------------------------------------------- + for (int i = 0; i < 48; i++) + { + pcSlope[i] = 1.0; // Default slope = 1 (preserves Raw energy) + pcIntercept[i] = 0.0; // Default intercept = 0 + } + + if(getenv("DATASET")) + dataset = std::string(getenv("DATASET")); + if(getenv("source_vertex")) + source_vertex = (double)std::atof(std::string(getenv("source_vertex")).c_str()); + std::cout << "Dataset set to " << dataset << std::endl; + std::cout << "source_vertex set to " << source_vertex << std::endl; + + + if(getenv("flipa")) { + int flip_offset = std::atoi(getenv("anode_offset")); + int yes_to_flip = std::atoi(getenv("flipa")); + if(yes_to_flip && flip_offset) { + std::cout << "Flipping anodes and offseting by " << flip_offset << " wires." << std::endl; + } else if(flip_offset){ + std::cout << "Offseting anodes without flip by " << flip_offset << " wires." << std::endl; + } + } + + fflush(stdout); + //usleep(4e5); + // Load PC Calibrations + std::ifstream inputFile("slope_intercept_results_"+dataset+".txt"); + if (inputFile.is_open()) + { + std::string line; + int index; + double slope, intercept; + while (std::getline(inputFile, line)) + { + std::stringstream ss(line); + ss >> index >> slope >> intercept; + if (index >= 0 && index <= 47) + { + pcSlope[index] = slope; + pcIntercept[index] = intercept; + } + } + inputFile.close(); + } + else + { + std::cerr << "Error opening slope_intercept.txt" << std::endl; + } + + // ... (Load QQQ Gains and Calibs - same as before) ... + { + std::string filename = "qqq_GainMatch.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double gainw, gainr; + while (infile >> det >> wedge >> ring >> gainw >> gainr) + { + qqqGain[det][wedge][ring] = gainw; + qqqGainValid[det][wedge][ring] = (gainw > 0); + // std::cout << "QQQ Gain Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " GainW " << gainw << " GainR " << gainr << std::endl; + } + infile.close(); + } + } + + { + std::string filename = "qqq_Calib.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double slope; + while (infile >> det >> wedge >> ring >> slope) + { + qqqCalib[det][wedge][ring] = slope; + qqqCalibValid[det][wedge][ring] = (slope > 0); + // std::cout << "QQQ Calib Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " Slope " << slope << std::endl; + } + infile.close(); + } + } + + { + std::ifstream infile("sx3cal/"+dataset+"/backgains.dat"); + std::string temp; + int backpos, frontpos, clkpos; + if (infile.is_open()) + while(infile>>clkpos>>temp>>frontpos>>temp>>backpos>>sx3BackGain[clkpos][frontpos][backpos]) + ;//std::cout << sx3BackGain[clkpos][frontpos][backpos] << std::endl; + infile.close(); + + infile.open("sx3cal/"+dataset+"/frontgains.dat"); + if (infile.is_open()) + while(infile>>clkpos>>temp>>temp>>frontpos>>sx3FrontOffset[clkpos][frontpos]>>sx3FrontGain[clkpos][frontpos]) + ;//std::cout << sx3FrontOffset[clkpos][frontpos] << " " << sx3FrontGain[clkpos][frontpos] << std::endl; + infile.close(); + + infile.open("sx3cal/"+dataset+"/rightgains.dat"); + if (infile.is_open()) + while(infile>>clkpos>>frontpos>>temp>>sx3RightGain[clkpos][frontpos]) { + sx3RightGain[clkpos][frontpos]=TMath::Abs(sx3RightGain[clkpos][frontpos]); + } + infile.close(); + } + + if(realtime) { + can1 = new TCanvas("wireindex","c1",0,0,640,480); + can2 = new TCanvas("3d","c2",650,0,640,480); + can1->cd(); + //can2->SetFillColor(30); + frame = new TH3D("frame","frame",1000,-100,100,1000,-100,100,1000,-200,200); + hha =new TH1F("hha","Anode Ecal vs wire#",48,-12,36); + hhc =new TH1F("hhc","Cathode Ecal vs wire#",48,-12,36); + hha->SetLineColor(kRed); + hha->GetYaxis()->SetRangeUser(0,16384); + hha->GetXaxis()->SetTitle("press any key, interrupt/refresh or double click to continue.."); + hha->Draw(); + hhc->Draw("SAME"); + can1->Modified(); + can1->Update(); + can1->BuildLegend(); + can2->cd(); + frame->Draw(); + for(int i=0; i<24; i++) { + plc[i] = new TPolyLine3D(2); + pla[i] = new TPolyLine3D(2); + pla[i]->SetPoint(0,pwinstance.An[i].first.X(),pwinstance.An[i].first.Y(),pwinstance.An[i].first.Z()); + pla[i]->SetPoint(1,pwinstance.An[i].second.X(),pwinstance.An[i].second.Y(),pwinstance.An[i].second.Z()); + plc[i]->SetPoint(0,pwinstance.Ca[i].first.X(),pwinstance.Ca[i].first.Y(),pwinstance.Ca[i].first.Z()); + plc[i]->SetPoint(1,pwinstance.Ca[i].second.X(),pwinstance.Ca[i].second.Y(),pwinstance.Ca[i].second.Z()); + plc[i]->SetLineStyle(kDotted); + pla[i]->SetLineStyle(kDotted); + pla[i]->SetLineWidth(1.); + plc[i]->SetLineWidth(1.); + plc[i]->Draw("same"); + pla[i]->Draw("same"); + plc[i]->SetLineColor(colors[i]); + pla[i]->SetLineColor(colors[i]); + } + crossoverg = new TGraph2D(1); + crossoverg->SetName("crossoverg"); + crossoverg->SetMarkerStyle(20); + crossoverg->SetMarkerColor(kBlue+3); + qqqg = new TGraph2D(1); + qqqg->SetName("qqqg"); + qqqg->SetMarkerColor(kRed); + qqqg->SetMarkerStyle(42); + + crossoverg->SetPoint(0,0,0,0); + qqqg->SetPoint(0,0,0,qqq_z); + crossoverg->Draw("P same"); + qqqg->Draw("P same"); + + trajectory=new TPolyLine3D(2); + trajectory->SetPoint(0,0,0,0); + trajectory->SetPoint(1,0,0,0); + trajectory->Draw("same"); + + can2->Modified(); + can2->Update(); + } +} + +Bool_t MakeVertex::Process(Long64_t entry) +{ + hitPos.Clear(); + qqqenergy = -1; + qqqtimestamp=-1; + HitNonZero = false; + bool qqq1000cut = false; + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + double timecut_low = getenv("timecut_low")?std::atof(getenv("timecut_low")):0; + double timecut_high = getenv("timecut_high")?std::atof(getenv("timecut_high")):1e15 ; + + if( pc.multi>0) { + for(int i=0; i= timecut_low) { + //good, keep it moving + } else { + return kTRUE; + } + } + } + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + std::vector sx3Events; + if(sx3.multi>1) { + std::array Fsx3; + //std::cout << "-----" << std::endl; + bool found_upstream_sx3=0; + for(int i=0; i=12) continue; + if(sx3.ch[i]>=8) { + int sx3ch=sx3.ch[i]-8; + sx3ch=(sx3ch+3)%4; + if(id>=12) { + found_upstream_sx3=1; + //std::cout << Form("f%d(",id) << sx3ch << "," << sx3.e[i] << ") " << std::flush; + } + //if(sx3ch==0 || sx3ch==3) continue; + double value=sx3.e[i]; + int gch = sx3.id[i]*4+(sx3.ch[i]-8); + if(id<12) Fsx3.at(id).fillevent("BACK",sx3ch,value); + Fsx3.at(id).ts = static_cast(sx3.t[i]); + plotter->Fill2D("sx3backs_all_raw",100,0,100,800,0,4096,gch,sx3.e[i]); + } else { + int sx3ch=sx3.ch[i]/2; + double value=sx3.e[i]; + if(id>=12) { + found_upstream_sx3=1; + //std::cout << Form("b%d(",id) << sx3ch << "," << value << ") " << std::flush; + } + if(sx3.ch[i]%2==0) { + Fsx3.at(id).fillevent("FRONT_L",sx3ch,value*sx3RightGain[id][sx3ch]); + } else { + Fsx3.at(id).fillevent("FRONT_R",sx3ch,value); + } + } + } //end for (i in sx3.multi) + //if(found_upstream_sx3) std::cout << std::endl; + + for(int id=0; id<24; id++) { + //std::cout << id << " " << Fsx3.at(id).valid_front_chans.size() << " " << Fsx3.at(id).valid_back_chans.size() << std::endl;; + try { + Fsx3.at(id).validate(); + } catch(std::exception exc) { + std::cout << "oops! anyway " << std::endl; + continue; + } + auto det = Fsx3.at(id); + bool no_charge_sharing_strict = det.valid_front_chans.size()==1 && det.valid_back_chans.size()==1; + if(det.valid) { + //std::cout << det.frontEL << " " << det.frontEL*sx3RightGain[id][det.stripF] << std::endl; + plotter->Fill2D("be_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF)+"_b"+std::to_string(det.stripB),200,-1,1,800,0,8192, + det.frontX,det.backE,"evsx"); + + //std::cout << sx3BackGain[id][det.stripF][det.stripB] << " " << sx3FrontGain[id][det.stripF] << std::endl; + plotter->Fill2D("matched_be_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF),200,-60,60,800,0,8192, + det.frontX*sx3FrontGain[id][det.stripF]+sx3FrontOffset[id][det.stripF],det.backE*sx3BackGain[id][det.stripF][det.stripB],"evsx_matched"); + //plotter->Fill2D("fe_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF)+"_"+std::to_string(det.stripB),200,-1,1,800,0,4096,det.frontX,det.backE,"evsx"); + plotter->Fill2D("l_vs_r_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF),800,0,4096,800,0,4096,det.frontEL,det.frontER,"l_vs_r"); + } + if(det.valid && (id ==9 || id==7 || id == 1 || id==3) && det.stripF!=DEFAULT_NULL && det.stripB!=DEFAULT_NULL) { + double z = det.frontX*sx3FrontGain[id][det.stripF]+sx3FrontOffset[id][det.stripF]; + double backE = det.backE*sx3BackGain[id][det.stripF][det.stripB]; + if(backE<2000) continue; + det.stripF=3-det.stripF; + double beta_n = 15.0 + TMath::ATan2((2*det.stripF-3)*40.30, 8.0*88.0*TMath::Cos(15.0*M_PI/180.0))*180./M_PI; //how much to add per strip to the starting position + double phi_n = ((-id+0.5)*30+beta_n); + phi_n+=45; + + if(getenv("flip180")) { + if(std::string(getenv("flip180"))=="1") { + //if(dataset=="17F") + phi_n+=180;//run 37 in 17F--> + } + } + phi_n*=M_PI/180.; //starting-position phi + strip contribution + Event sx3ev(TVector3(88.0*TMath::Cos(phi_n),88.0*TMath::Sin(phi_n),z),backE,-1,det.ts,-1,det.stripB+4*id,det.stripF+4*id); + sx3Events.push_back(sx3ev); + plotter->Fill2D("sx3backs_gm",100,0,100,800,0,8192,det.stripB+4*id,backE); + plotter->Fill2D("sx3backs_raw",100,0,100,800,0,8192,det.stripB+4*id,det.backE); + + //plotter->Fill2D("SX3CartesianPlot", 200, -100, 100, 200, -100, 100, 88.0*TMath::Cos(phi_n),88.0*TMath::Sin(phi_n), "hCalSX3"); + plotter->Fill2D("SX3CartesianPlot" + std::to_string(id), 200, -100, 100, 200, -100, 100, 88.0*TMath::Cos(phi_n),88.0*TMath::Sin(phi_n), "hCalSX3"); + + } + } + } + //return kTRUE; + // QQQ Processing + + int qqqCount = 0; + int qqqAdjCh = 0; + // REMOVE WHEN RERUNNING USING THE NEW CALIBRATION FILE + std::vector QQQ_Events, PC_Events; + std::vector QQQ_Events_Raw, PC_Events_Raw; + std::vector QQQ_Events2; //clustering done + + std::unordered_map> qvecr[4], qvecw[4]; + if(qqq.multi>1) { + //if(qqq.multi>=3) std::cout << "-----" << std::endl; + for(int i=0; iFill2D("QQQ_Index_Vs_Energy", 16 * 8, 0, 16 * 8, 2000, 0, 16000, qqq.index[i], qqq.e[i], "hRawQQQ"); + + for (int j = 0; j < qqq.multi; j++) { + if (j == i) + continue; + plotter->Fill2D("QQQ_Coincidence_Matrix", 16 * 8, 0, 16 * 8, 16 * 8, 0, 16 * 8, qqq.index[i], qqq.index[j], "hRawQQQ"); + } + + for (int k = 0; k < pc.multi; k++) { + if (pc.index[k] < 24 && pc.e[k] > 10) { + plotter->Fill2D("QQQ_Vs_Anode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + plotter->Fill2D("QQQ_Vs_PC_Index", 16 * 8, 0, 16 * 8, 24, 0, 24, qqq.index[i], pc.index[k], "hRawQQQ"); + } + else if (pc.index[k] >= 24 && pc.e[k] > 10) { + plotter->Fill2D("QQQ_Vs_Cathode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + } + } + + for (int j = i + 1; j < qqq.multi; j++) { + if (qqq.id[i] == qqq.id[j]) { + qqqCount++; + + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + double tWedge = 0.0; + + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + tWedge = static_cast(qqq.t[i]); + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i]; + tRing = static_cast(qqq.t[i]); + tWedge = static_cast(qqq.t[j]); + } + else + continue; + + plotter->Fill1D("Wedgetime_Vs_Ringtime", 100, -1000, 1000, tWedge - tRing, "hTiming"); + plotter->Fill2D("RingE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chRing + qqq.id[i] * 16, eRing, "hRawQQQ"); + plotter->Fill2D("WedgeE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chWedge + qqq.id[i] * 16, eWedge, "hRawQQQ"); + plotter->Fill2D("WedgeE_Vs_RingECal", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ"); + + if (qqqCalibValid[qqq.id[i]][chWedge][chRing]) { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + + if(eRingMeV/eWedgeMeV > 3.0 || eRingMeV/eWedgeMeV<1.0/3.0) continue; + if(eRingMeV<1.2 || eWedgeMeV<1.2) continue; + + double theta = 2 * TMath::Pi() * (-qqq.id[i] * 16 + (15-chWedge) + 0.5)/(16*4); + double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?" + //z used to be 75+30+23=128 + //we found a 12mm shift towards the vertex later --> 116 + Event qqqevent(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),qqq_z), eRingMeV, eWedgeMeV, tRing, tWedge,chRing+qqq.id[i]*16, chWedge+qqq.id[i]*16); + Event qqqeventr(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),qqq_z), eRing, eWedge, tRing, tWedge,chRing+qqq.id[i]*16, chWedge+qqq.id[i]*16); + if(qqq.id[i]>=1) { + QQQ_Events.push_back(qqqevent); + QQQ_Events_Raw.push_back(qqqeventr); + plotter->Fill2D("WedgeE_Vs_RingECal_selected", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ"); + } + plotter->Fill2D("QQQCartesianPlot", 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + plotter->Fill2D("QQQCartesianPlot" + std::to_string(qqq.id[i]), 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ"); + } + else + continue; + + + for (int k = 0; k < pc.multi; k++) + { + plotter->Fill2D("RingCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index" + std::to_string(qqq.id[i]), 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k]); + plotter->Fill2D("RingCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + + if (pc.index[k] < 24 && pc.e[k] > 10) + { + plotter->Fill2D("Timing_Difference_QQQ_PC", 500, -2000, 2000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + plotter->Fill2D("DelT_Vs_QQQRingECal", 500, -2000, 2000, 1000, 0, 10, tRing - static_cast(pc.t[k]), eRingMeV, "hTiming"); + plotter->Fill2D("CalibratedQQQEvsPCE_R", 1000, 0, 10, 2000, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("CalibratedQQQEvsPCE_W", 1000, 0, 10, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ"); + //if (tRing - static_cast(pc.t[k]) < -150) // proton tests, 27Al + if (tRing - static_cast(pc.t[k]) < -150) // proton tests, 27Al + { + PCAQQQTimeCut = true; + } + } + + if (pc.index[k] >= 24 && pc.e[k] > 10) { + if (tRing - static_cast(pc.t[k]) < -200) PCCQQQTimeCut = true; + //if (tRing - static_cast(pc.t[k]) > 200) PCCQQQTimeCut = true; + + plotter->Fill2D("Timing_Difference_QQQ_PC_Cathode", 500, -2000, 2000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + } + } //end of pc k loop + + if (!HitNonZero) { + //double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + //double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?" + double theta = 2 * TMath::Pi() * (-qqq.id[i] * 16 + (15-chWedge) + 0.5)/(16*4); + double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?" + + double x = rho * TMath::Cos(theta); + double y = rho * TMath::Sin(theta); + hitPos.SetXYZ(x, y, qqq_z); + //if(realtime) qqqg->SetPoint(0,hitPos.X(),hitPos.Y(),hitPos.Z()); + if(realtime) qqqg->AddPoint(hitPos.X(),hitPos.Y(),hitPos.Z()); + qqqenergy = eRingMeV; + qqqtimestamp = tRing; + HitNonZero = true; + } + } // if j==i + } //j loop end + } //i loop end + + PCQQQTimeCut = PCAQQQTimeCut && PCCQQQTimeCut; + plotter->Fill1D("QQQ_Multiplicity", 10, 0, 10, qqqCount, "hRawQQQ"); + + + typedef std::unordered_map> WireEvent; //this stores nearest neighbour wire events, or a 'cluster' + WireEvent aWireEvents, cWireEvents; //naming for book keeping + aWireEvents.clear(); + aWireEvents.reserve(24); + if(realtime) { + hha->Reset(); + hhc->Reset(); + } + // PC Gain Matching and Filling + double anodeT = -99999; + double cathodeT = 99999; + int anodeIndex = -1; + int cathodeIndex = -1; + for (int i = 0; i < pc.multi; i++) + { + //std::cout << pc.index[i] << " " << pc.e[i] << " " << std::endl; + if (pc.e[i] > 10) + { + plotter->Fill2D("PC_Index_Vs_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], static_cast(pc.e[i]), "hRawPC"); + } else { + continue; + } + + if (pc.index[i] < 48) + { + pc.e[i] = pcSlope[pc.index[i]] * pc.e[i] + pcIntercept[pc.index[i]]; + plotter->Fill2D("PC_Index_VS_GainMatched_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], pc.e[i], "hGMPC"); + } + + if (pc.index[i] < 24) + { + anodeT = static_cast(pc.t[i]); + anodeIndex = pc.index[i]; + + if(getenv("flipa")) { + int flip_offset = std::atoi(getenv("anode_offset")); + int yes_to_flip = std::atoi(getenv("flipa")); + if(yes_to_flip && flip_offset) { + int flipped_index = (23-anodeIndex+flip_offset)%24; + aWireEvents[flipped_index] = std::tuple(flipped_index,pc.e[i],static_cast(pc.t[i])); + //std::cout << "Flipping anodes and offseting by " << flip_offset << " wires." << std::endl; + } else if(flip_offset){ + int offset_index = (anodeIndex+flip_offset)%24; + aWireEvents[pc.index[i]] = std::tuple(offset_index,pc.e[i],static_cast(pc.t[i])); + //std::cout << "Offseting anodes without flip by " << offset_index << " wires." << std::endl; + } else + aWireEvents[pc.index[i]] = std::tuple(pc.index[i],pc.e[i],static_cast(pc.t[i])); + } else + aWireEvents[pc.index[i]] = std::tuple(pc.index[i],pc.e[i],static_cast(pc.t[i])); + if(realtime) hha->SetBinContent(hha->FindFixBin(anodeIndex),pc.e[i]); + } + else + { + cathodeT = static_cast(pc.t[i]); + cathodeIndex = pc.index[i] - 24; + if(getenv("flipc")) { + int flip_offset = std::atoi(getenv("flipc")); + int flipped_index = (cathodeIndex+flip_offset)%24; + cWireEvents[flipped_index] = std::tuple(flipped_index,pc.e[i],static_cast(pc.t[i])); + } else { + cWireEvents[pc.index[i]-24] = std::tuple(pc.index[i]-24,pc.e[i],static_cast(pc.t[i])); + } + + if(realtime) hhc->SetBinContent(hhc->FindFixBin(cathodeIndex),pc.e[i]); + } + + if (anodeT != -99999 && cathodeT != 99999) + { + for (int j = 0; j < qqq.multi; j++) + { + plotter->Fill1D("PC_Time_qqq", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + plotter->Fill2D("PC_Time_Vs_QQQ_ch", 200, -2000, 2000, 16 * 8, 0, 16 * 8, anodeT - cathodeT, qqq.ch[j], "hTiming"); + plotter->Fill2D("PC_Time_vs_AIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, anodeIndex, "hTiming"); + plotter->Fill2D("PC_Time_vs_CIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, cathodeIndex, "hTiming"); + // plotter->Fill1D("PC_Time_A" + std::to_string(anodeIndex) + "_C" + std::to_string(cathodeIndex), 200, -1000, 1000, anodeT - cathodeT, "TimingPC"); + } + + for (int j = 0; j < sx3.multi; j++) + { + plotter->Fill1D("PC_Time_sx3", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + for(auto sx3event : sx3Events) { + bool TCC = sx3event.Time1 - cathodeT < 0; + bool TCA = sx3event.Time1 - anodeT < 0; + //plotter->Fill2D("sx3_z_phi_awire"+std::to_string(anodeIndex)+"_TC"+std::to_string(TCA), 400,-100,100, 200, -200,200,sx3event.pos.Z(), sx3event.pos.Phi()*180/M_PI ); + //plotter->Fill2D("sx3_z_phi_cwire"+std::to_string(cathodeIndex)+"_TC"+std::to_string(TCC), 400,-100,100, 200, -200,200,sx3event.pos.Z(), sx3event.pos.Phi()*180/M_PI ); + } + + plotter->Fill1D("PC_Time", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + + for (int j = i + 1; j < pc.multi; j++) + { + plotter->Fill2D("PC_Coincidence_Matrix", 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("PC_Coincidence_Matrix_anodeMinusCathode_lt_-200_" + std::to_string(anodeT - cathodeT < -200), 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("Anode_V_Anode", 24, 0, 24, 24, 0, 24, pc.index[i], pc.index[j], "hGMPC"); + } + } + anodeHits.clear(); + cathodeHits.clear(); + corrcatMax.clear(); + + int aID = 0; + int cID = 0; + double aE = 0; + double cE = 0; + double aESum = 0; + double cESum = 0; + double aEMax = 0; + double cEMax = 0; + int aIDMax = 0; + int cIDMax = 0; + + for (int i = 0; i < pc.multi; i++) { + // if (pc.e[i] > 100) + { + if (pc.index[i] < 24) { + anodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + } + else if (pc.index[i] >= 24) { + cathodeHits.push_back(std::pair(pc.index[i] - 24, pc.e[i])); + } + } + } + + std::sort(anodeHits.begin(),anodeHits.end(),[](std::pair a, std::pair b) { + return a.first < b.first; + }); + + std::sort(cathodeHits.begin(),cathodeHits.end(),[](std::pair a, std::pair b) { + return a.first < b.first; + }); + + //clusters = collection of (collection of wires) where each wire is (index, energy, timestamp) + std::vector>> aClusters = pwinstance.Make_Clusters(aWireEvents); + std::vector>> cClusters = pwinstance.Make_Clusters(cWireEvents); + + std::vector> sumE_AC; + for(auto aCluster: aClusters) { + for(auto cCluster: cClusters) { + if(aCluster.size() ==0 ) continue; + if(cCluster.size() ==0 ) continue; + //both have at least 1, here. Keep the a1, c1 events + auto [crossover,alpha,apSumE,cpSumE,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE] = pwinstance.FindCrossoverProperties(aCluster, cCluster); + if(alpha!=9999999 && apSumE!=-1) { + //Event PCEvent(crossover,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE); + //Event PCEvent(crossover,apSumE,cpSumE,apTSMaxE,cpTSMaxE); + Event PCEvent(crossover,apSumE,cpMaxE,apTSMaxE,cpTSMaxE); //run12 shows cathode-max and anode-sum provide best dE signals. + //std::cout << apSumE << " " << crossover.Perp() << " " << apMaxE << " " << apTSMaxE << std::endl; + PCEvent.multi1=aCluster.size(); + PCEvent.multi2=cCluster.size(); + PC_Events.push_back(PCEvent); + sumE_AC.push_back(std::pair(apSumE,cpSumE)); + } else { + ;//std::cout << "AAAA " << std::endl; + } + } + } + + /*for(auto sx3event: sx3Events) { + for(int i=0; i<24; i++) { + if(aWireEvents.find(i) != aWireEvents.end()) { + auto awire = aWireEvents[i]; + if(sx3event.Time1 -(double)std::get<2>(awire)< -100) { + plotter->Fill2D("sx3_z_phi2_awire"+std::to_string(std::get<0>(awire)), 400,-100,100, 100, -200,200,sx3event.pos.Z(), sx3event.pos.Phi()*180/M_PI ); + plotter->Fill2D("sx3_z_strip#_awire"+std::to_string(std::get<0>(awire)), 400,-100,100, 100, -50,50,sx3event.pos.Z(), sx3event.ch2); + + //std::cout << sx3event.pos.Z() << " " << std::get<0>(awire) << " " << std::get<0>(awire) - sx3event.Time1 << std::endl; + } + } + + if(cWireEvents.find(i) != cWireEvents.end()) { + auto cwire = cWireEvents[i]; + if(sx3event.Time1 -(double)std::get<2>(cwire) < -100) { + plotter->Fill2D("sx3_z_phi2_cwire"+std::to_string(std::get<0>(cwire)),400,-100,100, 100, -200,200,sx3event.pos.Z(), sx3event.pos.Phi()*180/M_PI ); + plotter->Fill2D("sx3_z_strip#_cwire"+std::to_string(std::get<0>(cwire)),400,-100,100, 100, -50,50,sx3event.pos.Z(), sx3event.ch2 ); + } + } + } + }*/ + + if(QQQ_Events.size() && PC_Events.size()) + plotter->Fill2D("PCEv_vs_QQQEv",20,0,20,20,0,20,QQQ_Events.size(),PC_Events.size()); + + plotter->Fill2D("ac_vs_cc",20,0,20,20,0,20,aClusters.size(),cClusters.size(),"wiremult"); + for(auto cluster: aClusters) { + plotter->Fill1D("aClusters"+std::to_string(aClusters.size()),20,-5,15,cluster.size(),"wiremult"); + } + for(auto cluster: cClusters) { + plotter->Fill1D("cClusters"+std::to_string(cClusters.size()),20,-5,15,cluster.size(),"wiremult"); + } + + if(cClusters.size() && aClusters.size()) { + plotter->Fill2D("ac_vs_cc_ign0",20,0,20,20,0,20,aClusters.size(),cClusters.size(),"wiremult"); + } + + for(auto pcevent:PC_Events) { + if(aClusters.size()==1 && cClusters.size() == 1) { + //plotter->Fill1D("pcz_a"+std::to_string(aClusters.at(0).size())+"_c"+std::to_string(cClusters.at(0).size()),800,-200,200,pcevent.pos.Z(),"wiremult"); + std::string detid="_+_"; + if(sx3Events.size()) detid="+sx3"; + if(QQQ_Events.size()) detid="+qqq"; + //plotter->Fill1D("pcz_a"+std::to_string(aClusters.at(0).size())+"_c"+std::to_string(cClusters.at(0).size())+detid,800,-200,200,pcevent.pos.Z(),"wiremult"); + } + + PCSX3TimeCut=false; + for(auto sx3event:sx3Events) { + plotter->Fill1D("dt_pcA_sx3B"+std::to_string(sx3event.ch2),640,-2000,2000,sx3event.Time1 - pcevent.Time1,"hTiming"); + plotter->Fill1D("dt_pcC_sx3B"+std::to_string(sx3event.ch2),640,-2000,2000,sx3event.Time1 - pcevent.Time2,"hTiming"); + if(sx3event.Time1 - pcevent.Time1 < 0)//-150 for alphas + PCASX3TimeCut = 1; + if(sx3event.Time1 - pcevent.Time2 < 0)//-200 for alphas + PCCSX3TimeCut = 1; + PCSX3TimeCut = PCASX3TimeCut && PCCSX3TimeCut; + + plotter->Fill1D("dt_pcA_sx3B",640,-2000,2000,sx3event.Time1 - pcevent.Time1); + plotter->Fill1D("dt_pcC_sx3B",640,-2000,2000,sx3event.Time1 - pcevent.Time2); + plotter->Fill2D("dt_pcA_vs_sx3RE",640,-2000,2000,400,0,10,sx3event.Time1-pcevent.Time1, sx3event.Energy1*0.001); + plotter->Fill2D("dE_E_Anodesx3B",400,0,10,800,0,40000,sx3event.Energy1*0.001,pcevent.Energy1); + plotter->Fill2D("dE_E_Cathodesx3B",400,0,10,800,0,10000,sx3event.Energy1*0.001,pcevent.Energy2); + plotter->Fill2D("sx3phi_vs_pcphi"+std::to_string(sx3event.Time1 - pcevent.Time1<-150),100,-360,360,100,-360,360,sx3event.pos.Phi()*180/M_PI,pcevent.pos.Phi()*180/M_PI); + if(PCSX3TimeCut) { + plotter->Fill1D("dt_pcA_sx3B_timecut",640,-2000,2000,sx3event.Time1 - pcevent.Time1); + plotter->Fill1D("dt_pcC_sx3B_timecut",640,-2000,2000,sx3event.Time1 - pcevent.Time2); + plotter->Fill2D("xyplot_sx3"+std::to_string(sx3event.ch2/4),100,-100,100,100,-100,100,sx3event.pos.X(),sx3event.pos.Y()); + plotter->Fill2D("xyplot_sx3"+std::to_string(sx3event.ch2/4),100,-100,100,100,-100,100,pcevent.pos.X(),pcevent.pos.Y()); + plotter->Fill2D("pcz_vs_pcphi_TimeCut",600,-200,200,120,-360,360,pcevent.pos.Z(),pcevent.pos.Phi()*180/M_PI); //x-axis is all Si det, y-axis is PC anode+cathode only + } + double sx3rho = 88.0;//approximate barrel radius + double sx3z = sx3event.pos.Z()+(75.0/2.0)-3.0; //w.r.t target origin at 90 for run12 + double pcz = pcevent.pos.Z(); + double calcsx3theta = TMath::ATan2(sx3rho-z_to_crossover_rho(pcz),sx3z-pcz); + plotter->Fill2D("dE2_E_Anodesx3B",400,0,10,800,0,40000,sx3event.Energy1*0.001,pcevent.Energy1*TMath::Sin(calcsx3theta)); + plotter->Fill2D("dE2_E_Cathodesx3B",400,0,10,800,0,10000,sx3event.Energy1*0.001,pcevent.Energy2*TMath::Sin(calcsx3theta)); + + + double sx3theta = TMath::ATan2(sx3rho,sx3z-source_vertex); + double pczguess = 37.0/TMath::Tan(sx3theta) + source_vertex; + double pcz_guess_int = z_to_crossover_rho(pcevent.pos.Z())/TMath::Tan(sx3theta) + source_vertex; + double sinTheta = TMath::Sin(sx3theta); + + TVector3 x2(pcevent.pos), x1(sx3event.pos); + TVector3 v = x2-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 vector_closest_to_z_sx3 = x1 + t_minimum*v; + plotter->Fill1D("VertexReconZ_SX3"+std::to_string(PCSX3TimeCut),600,-1300,1300,vector_closest_to_z_sx3.Z(),"hPCZSX3"); + plotter->Fill2D("VertexReconXY_SX3"+std::to_string(PCSX3TimeCut),100,-100,100,100,-100,100,vector_closest_to_z_sx3.X(),vector_closest_to_z_sx3.Y(),"hPCZSX3"); + + plotter->Fill2D("pcz_vs_time",2000,0,2000,600,-200,200,pcevent.Time1*1e-9,pcevent.pos.Z()); //x-axis is all Si det, y-axis is PC anode+cathode only + plotter->Fill2D("pcphi_vs_time",2000,0,2000,180,-360,360,pcevent.Time1*1e-9,pcevent.pos.Phi()*180./M_PI); //x-axis is all Si det, y-axis is PC anode+cathode only + + //plotter->Fill2D("pcz_vs_time_strip"+std::to_string(sx3event.ch2),2000,0,2000,600,-200,200,pcevent.Time1*1e-9,pcevent.pos.Z()); //x-axis is all Si det, y-axis is PC anode+cathode only + plotter->Fill2D("sx3phi_vs_time",2000,0,2000,180,-360,360,pcevent.Time1*1e-9,sx3event.pos.Phi()*180./M_PI); //x-axis is all Si det, y-axis is PC anode+cathode only + + + plotter->Fill2D("pcz_vs_sx3pczguess",600,-200,200,600,-200,200,pczguess,pcevent.pos.Z()); //x-axis is all Si det, y-axis is PC anode+cathode only + if(pcevent.multi1==1 && pcevent.multi2==2) { + plotter->Fill2D("pcz_vs_sx3pczguess_A1C2",600,-200,200,600,-200,200,pczguess,pcevent.pos.Z()); + double pcz_fix = pcfix_func.Eval(pcevent.pos.Z()); + + TVector3 x2f(pcevent.pos.X(),pcevent.pos.Y(),pcz_fix); + TVector3 v = x2f-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 r_rhoMin_fix = x1 + t_minimum*v; + plotter->Fill1D("VertexRecon_pczfix_sx3",600,-200,200,r_rhoMin_fix.Z()); + plotter->Fill1D("pczfix_A1C2_1d_sx3",600,-200,200,pcz_fix); + plotter->Fill2D("pczfix_vs_sx3pczguess_A1C2",600,-200,200,600,-200,200,pczguess,pcz_fix); + plotter->Fill2D("pcz_vs_sx3pczguess_A1C2_strip"+std::to_string(sx3event.ch2),300,-200,200,600,-200,200,pczguess,pcevent.pos.Z()); + + double sinTheta_customV = TMath::Sin((sx3event.pos - TVector3(0,0,r_rhoMin_fix.Z())).Theta()); + if(TMath::Abs(r_rhoMin_fix.Z())<200.0) { + plotter->Fill2D("dE3_E_AnodeSX3B_A1C2_(vertex_fix_z/20)="+std::to_string(floor(r_rhoMin_fix.Z()/20.0)),400,0,10,800,0,40000,sx3event.Energy1*0.001,pcevent.Energy1*sinTheta_customV); + plotter->Fill2D("dE3_E_CathodeSX3B_A1C2_(vertex_fix_z/20)="+std::to_string(floor(r_rhoMin_fix.Z()/20.0)),400,0,10,800,0,10000,sx3event.Energy1*0.001,pcevent.Energy2*sinTheta_customV); + } + } + if(pcevent.multi1==1 && pcevent.multi2==3) { + plotter->Fill2D("pcz_vs_sx3pczguess_A1C3",600,-200,200,600,-200,200,pczguess,pcevent.pos.Z()); + plotter->Fill2D("pcz_vs_sx3pczguess_A1C3_strip"+std::to_string(sx3event.ch2),300,-200,200,600,-200,200,pczguess,pcevent.pos.Z()); + } + + plotter->Fill2D("pcz_vs_sx3pczguess_int",600,-200,200,600,-200,200,pcz_guess_int,pcevent.pos.Z()); //x-axis is all Si det, y-axis is PC anode+cathode only + plotter->Fill2D("pcz_vs_sx3pczguess_strip"+std::to_string(sx3event.ch2),300,-200,200,600,-200,200,pczguess,pcevent.pos.Z()); + //plotter->Fill2D("pcz_vs_sx3pczguess_phi"+std::to_string(sx3event.pos.Phi()*180/M_PI),300,0,200,600,-200,200,pczguess,pcevent.pos.Z()); + + /*plotter->Fill2D("pcz_vs_sx3z_strip="+std::to_string(sx3event.ch2),300,0,100,600,-200,200,sx3z,pcevent.pos.Z(),"sx3_vs_pc_zcorr"); + plotter->Fill2D("pcz_vs_sx3z_strip="+std::to_string(sx3event.ch2)+"_a"+std::to_string(pcevent.multi1)+"_c"+std::to_string(pcevent.multi2),300,0,100,600,-200,200,sx3z,pcevent.pos.Z(),"sx3_vs_pc_zcorr"); + + plotter->Fill2D("pcdEC_vs_sx3z_strip="+std::to_string(sx3event.ch2)+"_a"+std::to_string(pcevent.multi1)+"_c"+std::to_string(pcevent.multi2),800,0,20000,600,-200,200,pcevent.Energy2,sx3z,"sx3_vs_pc_zcorr"); + plotter->Fill2D("pcdEA_vs_sx3z_strip="+std::to_string(sx3event.ch2)+"_a"+std::to_string(pcevent.multi1)+"_c"+std::to_string(pcevent.multi2),800,0,20000,600,-200,200,pcevent.Energy1,sx3z,"sx3_vs_pc_zcorr");*/ + + /*for(auto cc: cClusters) + for(auto ac: aClusters) { + plotter->Fill2D("pcz_sx3_phicut_a"+std::to_string(ac.size())+"_c"+std::to_string(cc.size())+"_sx3guess",300,0,200,600,-200,200,sx3z,pcevent.pos.Z(),"hPCZSX3"); + if(ac.size()==2 && cc.size()==1) { + plotter->Fill2D("pcz_sx3_phicut_a("+std::to_string(std::get<0>(ac.at(0)))+","+std::to_string(std::get<0>(ac.at(1)))+")_c"+std::to_string(std::get<0>(cc.at(0)))+"_sx3guess",300,0,200,600,-200,200,sx3z,pcevent.pos.Z(),"hPCZSX3"); + plotter->Fill2D("a2c1_vs_sx3_strip",24,0,24,64,0,64,0.5*(std::get<0>(ac.at(0))+std::get<0>(ac.at(1))),sx3event.ch2,"hPCZSX3"); + //plotter->Fill2D("sx3phi_vs_pcphi"+std::to_string(sx3event.Time1 - pcevent.Time1<-150)+"_a("+std::to_string(std::get<0>(ac.at(0)))+","+std::to_string(std::get<0>(ac.at(1)))+")_c"+std::to_string(std::get<0>(cc.at(0))),100,-360,360,100,-360,360,sx3event.pos.Phi()*180/M_PI,pcevent.pos.Phi()*180/M_PI); + } + if(cc.size()==2 && ac.size()==1) { + plotter->Fill2D("pcz_sx3_phicut_c("+std::to_string(std::get<0>(cc.at(0)))+","+std::to_string(std::get<0>(cc.at(1)))+")_a"+std::to_string(std::get<0>(ac.at(0)))+"_sx3guess",300,0,200,600,-200,200,sx3z,pcevent.pos.Z(),"hPCZSX3"); + plotter->Fill2D("c2a1_vs_sx3_strip",24,0,24,64,0,64,0.5*(std::get<0>(cc.at(0))+std::get<0>(cc.at(1))),sx3event.ch2,"hPCZSX3"); + plotter->Fill2D("sx3phi_vs_pcphi"+std::to_string(sx3event.Time1 - pcevent.Time1<-150)+"_c("+std::to_string(std::get<0>(cc.at(0)))+","+std::to_string(std::get<0>(cc.at(1)))+")_a"+std::to_string(std::get<0>(ac.at(0))),100,-360,360,100,-360,360,sx3event.pos.Phi()*180/M_PI,pcevent.pos.Phi()*180/M_PI); + //plotter->Fill2D("pcz_vs_sx3z_2C1A_phiCut_TC"+std::to_string(PCSX3TimeCut),300,0,200,600,-400,400,sx3z,pcevent.pos.Z()); + } + + if(ac.size()==1 && cc.size()==1) { + plotter->Fill2D("pcz_sx3_phicut_a("+std::to_string(std::get<0>(ac.at(0)))+")_c"+std::to_string(std::get<0>(cc.at(0)))+"_sx3guess",300,0,200,600,-200,200,sx3z,pcevent.pos.Z(),"hPCZSX3"); + //plotter->Fill2D("a2c1_vs_sx3_strip",24,0,24,64,0,64,0.5*(std::get<0>(ac.at(0))+std::get<0>(ac.at(1))),sx3event.ch2,"hPCZSX3"); + //plotter->Fill2D("sx3phi_vs_pcphi"+std::to_string(sx3event.Time1 - pcevent.Time1<-150)+"_a("+std::to_string(std::get<0>(ac.at(0)))+")_c"+std::to_string(std::get<0>(cc.at(0))),100,-360,360,100,-360,360,sx3event.pos.Phi()*180/M_PI,pcevent.pos.Phi()*180/M_PI); + } + }*/ //end for + + bool sx3PhiCut = (TMath::Abs(sx3event.pos.Phi()-pcevent.pos.Phi()) < 45.0*M_PI/180.); + plotter->Fill1D("pcz_sx3Coinc_phiCut"+std::to_string(sx3PhiCut)+"_TC"+std::to_string(PCSX3TimeCut),300,0,200,sx3z); + plotter->Fill2D("pcz_vs_sx3z_phiCut"+std::to_string(sx3PhiCut)+"_TC"+std::to_string(PCSX3TimeCut),300,0,200,600,-400,400,sx3z,pcevent.pos.Z()); + + plotter->Fill2D("sx3E_vs_sx3z"+std::to_string(sx3event.ch2),400,0,10,300,0,200,sx3event.Energy1*0.001,sx3z); + + plotter->Fill2D("pcdEA_vs_sx3z",800,0,20000,300,0,200,pcevent.Energy1,sx3z); + plotter->Fill2D("pcdEC_vs_sx3z",800,0,20000,300,0,200,pcevent.Energy2,sx3z); + + plotter->Fill2D("pcdEA_vs_sx3z"+std::to_string(sx3event.ch2),800,0,20000,300,0,200,pcevent.Energy1,sx3z,"pcE_vs_sx3pos"); + plotter->Fill2D("pcdEC_vs_sx3z"+std::to_string(sx3event.ch2),800,0,20000,300,0,200,pcevent.Energy2,sx3z,"pcE_vs_sx3pos"); + + plotter->Fill2D("pcdE2A_vs_sx3z",800,0,20000,300,0,200,pcevent.Energy1*sinTheta,sx3z); + plotter->Fill2D("pcdE2C_vs_sx3z",800,0,20000,300,0,200,pcevent.Energy2*sinTheta,sx3z); + plotter->Fill2D("phi_vs_stripnum",180,-180,180,48,0,48,pcevent.pos.Phi()*180./M_PI,sx3event.ch2); + plotter->Fill2D("E_theta_AnodeSX3",400,-20,180,300,0,15,sx3theta*180/M_PI,sx3event.Energy1*0.001); + } + if(PCSX3TimeCut) { + plotter->Fill1D("PCZ_sx3",800,-200,200,pcevent.pos.Z(),"hPCZSX3"); + plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut"); + /*for(auto cc: cClusters) + for(auto ac: aClusters) { + plotter->Fill1D("PCZsx3_phicut_a"+std::to_string(ac.size())+"_c"+std::to_string(cc.size()),800,-200,200,pcevent.pos.Z(),"hPCZSX3"); + }*/ + } + }//end PC-SX3 coincidence + + for(auto pcevent: PC_Events) { + for(auto qqqevent: QQQ_Events) { + plotter->Fill1D("dt_pcA_qqqR",640,-2000,2000,qqqevent.Time1 - pcevent.Time1); + plotter->Fill2D("dt_pcA_qqqR_vs_qqqRE",640,-2000,2000,400,0,10,qqqevent.Time1-pcevent.Time1, qqqevent.Energy1); + plotter->Fill1D("dt_pcC_qqqW",640,-2000,2000,qqqevent.Time2 - pcevent.Time2); + plotter->Fill2D("phiPC_vs_phiQQQ",180,-360,360,180,-360,360,qqqevent.pos.Phi()*180/M_PI,pcevent.pos.Phi()*180/M_PI); + double sinTheta = TMath::Sin((qqqevent.pos - TVector3(0,0,source_vertex)).Theta());///TMath::Sin((TVector3(51.5,0,128.) - TVector3(0,0,85)).Theta()); + + TVector3 x2(pcevent.pos); + TVector3 x1(qqqevent.pos); + TVector3 v = x2-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 r_rhoMin = x1 + t_minimum*v; + + + /*if((qqqevent.pos - r_rhoMin).Theta()*180/M_PI > 52) { + plotter->Fill2D("dE3_E_AnodeQQQR_outer",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta_customV,"customVertex"); + plotter->Fill2D("dE3_E_CathodeQQQR_outer",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2*sinTheta_customV,"customVertex"); + } else { + plotter->Fill2D("dE3_E_AnodeQQQR_inner",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta_customV,"customVertex"); + plotter->Fill2D("dE3_E_CathodeQQQR_inner",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2*sinTheta_customV,"customVertex"); + }*/ + + //bool timecut = (qqqevent.Time1 - pcevent.Time1 < -150); + bool timecut = (qqqevent.Time1 - pcevent.Time1 < -150); + if(timecut) {// && qqqevent.pos.Phi() <= pcevent.pos.Phi()+TMath::Pi()/4. && qqqevent.pos.Phi() >= pcevent.pos.Phi()-TMath::Pi()/4. ) { + + plotter->Fill2D("dE_E_AnodeQQQR",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1); + plotter->Fill2D("dE_E_CathodeQQQR",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2); + + /*if((qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI > 52) { + plotter->Fill2D("dE2_E_AnodeQQQR_outer",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta); + plotter->Fill2D("dE2_E_CathodeQQQR_outer",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2*sinTheta); + plotter->Fill2D("dE_E_AnodeQQQR_outer",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1); + plotter->Fill2D("dE_E_CathodeQQQR_outer",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2); + } else { + plotter->Fill2D("dE2_E_AnodeQQQR_inner",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta); + plotter->Fill2D("dE2_E_CathodeQQQR_inner",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2*sinTheta); + plotter->Fill2D("dE_E_AnodeQQQR_inner",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1); + plotter->Fill2D("dE_E_CathodeQQQR_inner",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2); + }*/ + + + plotter->Fill2D("qqqphi_vs_time",2000,0,2000,180,-360,360,pcevent.Time1*1e-9,qqqevent.pos.Phi()*180./M_PI); //x-axis is all Si det, y-axis is PC anode+cathode only + //plotter->Fill2D("dE_E_CathodeQQQ(R/4)"+std::to_string(floor((qqqevent.ch1%16)/4)),400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2,"customVertex"); + //plotter->Fill2D("dE_E_AnodeQQQ(R/4)"+std::to_string(floor((qqqevent.ch1%16)/4)),400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1,"customVertex"); + + + plotter->Fill1D("dt_pcA_qqqR_timecut",640,-2000,2000,qqqevent.Time1 - pcevent.Time1); + plotter->Fill1D("dt_pcC_qqqW_timecut",640,-2000,2000,qqqevent.Time2 - pcevent.Time2); + plotter->Fill2D("dE_theta_AnodeQQQR",75,0,90,400,0,20000,(qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI,pcevent.Energy1); + plotter->Fill2D("dE2_theta_AnodeQQQR",75,0,90,400,0,20000,(qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI,pcevent.Energy1*sinTheta); + plotter->Fill2D("phiPC_vs_phiQQQ_TimeCut",180,-360,360,180,-360,360,qqqevent.pos.Phi()*180/M_PI,pcevent.pos.Phi()*180/M_PI); + + plotter->Fill2D("E_theta_AnodeQQQR",75,0,90,300,0,15,(qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI,qqqevent.Energy1); + plotter->Fill2D("E2_theta_AnodeQQQR",75,0,90,300,0,15,(qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI,qqqevent.Energy1); + plotter->Fill2D("Etot2_theta_AnodeQQQR",75,0,90,300,0,15,(qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI,qqqevent.Energy1+pcevent.Energy1*anode_gain*sinTheta); + + plotter->Fill2D("dE_theta_CathodeQQQR",75,0,90,800,0,10000,(qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI,pcevent.Energy2); + plotter->Fill2D("dE2_theta_CathodeQQQR",75,0,90,800,0,10000,(qqqevent.pos - TVector3(0,0,source_vertex)).Theta()*180/M_PI,pcevent.Energy2*sinTheta); + + plotter->Fill2D("dE_phi_AnodeQQQR",100,-180,180,800,0,40000,(qqqevent.pos - TVector3(0,0,source_vertex)).Phi()*180/M_PI,pcevent.Energy1); + + plotter->Fill2D("dE_phi_CathodeQQQR",100,-180,180,800,0,10000,(qqqevent.pos - TVector3(0,0,source_vertex)).Phi()*180/M_PI,pcevent.Energy2); + plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut"); + //plotter->Fill1D("PCZ_phicut_a"+std::to_string(aClusters.at(0).size())+"_c"+std::to_string(cClusters.at(0).size()),800,-200,200,pcevent.pos.Z(),"wiremult"); + + double pcz_guess_37 = 37./TMath::Tan((qqqevent.pos-TVector3(0,0,source_vertex)).Theta()) + source_vertex; + plotter->Fill2D("pczguess_vs_pc_37",180,0,200,150,0,200,pcz_guess_37,pcevent.pos.Z(),"phicut"); + + double pcz_guess_42 = 42./TMath::Tan((qqqevent.pos-TVector3(0,0,source_vertex)).Theta()) + source_vertex; + plotter->Fill2D("pczguess_vs_pc_42",180,0,200,150,0,200,pcz_guess_42,pcevent.pos.Z(),"phicut"); + + double pcz_guess_int = z_to_crossover_rho(pcevent.pos.Z())/TMath::Tan((qqqevent.pos-TVector3(0,0,source_vertex)).Theta()) + source_vertex; + //plotter->Fill2D("pczguess_vs_pc_int",180,0,200,150,0,200,pcz_guess_int,pcevent.pos.Z(),"phicut"); + plotter->Fill2D("pczguess_vs_pc_int",400,-200,200,600,-400,400,pcz_guess_int,pcevent.pos.Z(),"phicut"); + if(pcevent.multi1==1 && pcevent.multi2==2) { + double pcz_fix = pcfix_func.Eval(pcevent.pos.Z()); + TVector3 x2f(pcevent.pos.X(),pcevent.pos.Y(),pcz_fix); + TVector3 v = x2f-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 r_rhoMin_fix = x1 + t_minimum*v; + + double sinTheta_customV = TMath::Sin((qqqevent.pos - TVector3(0,0,r_rhoMin_fix.Z())).Theta()); + plotter->Fill2D("dE3_E_CathodeQQQW_A1C2",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2*sinTheta_customV); + plotter->Fill2D("dE3_E_AnodeQQQR_A1C2",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta_customV); + + plotter->Fill1D("VertexRecon_pczfix_qqq",600,-200,200,r_rhoMin_fix.Z()); + if(TMath::Abs(r_rhoMin_fix.Z())<200.0) { + plotter->Fill2D("dE3_E_AnodeQQQR_A1C2_(vertex_fix_z/20)="+std::to_string(floor(r_rhoMin_fix.Z()/20.0)),400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta_customV); + plotter->Fill2D("dE3_E_CathodeQQQR_A1C2_(vertex_fix_z/20)="+std::to_string(floor(r_rhoMin_fix.Z()/20.0)),400,0,10,800,0,10000,qqqevent.Energy1,pcevent.Energy2*sinTheta_customV); + } + + plotter->Fill1D("pczfix_A1C2_1d_qqq",600,-200,200,pcz_fix); + plotter->Fill2D("pczfix_vs_qqqpczguess_A1C2",600,-200,200,600,-200,200,pcz_guess_int,pcz_fix); + plotter->Fill2D("pczguess_vs_pc_int_A1C2",400,-200,200,600,-400,400,pcz_guess_int,pcevent.pos.Z(),"phicut"); + } + double qqqrho = qqqevent.pos.Perp(); + double qqqz = (qqqevent.pos - TVector3(0,0,source_vertex)).Z(); + double tan_theta = qqqrho/qqqz; + double pcz_guess_int2 = z_to_crossover_rho(pcevent.pos.Z())/tan_theta + source_vertex; + plotter->Fill2D("pczguess_vs_pc_int2",180,0,200,150,0,200,pcz_guess_int2,pcevent.pos.Z(),"phicut"); + + + + double qqqz2 = (qqqevent.pos - r_rhoMin).Z(); + double tan_theta2 = qqqrho/qqqz2; + double pcz_guess_int3 = z_to_crossover_rho(pcevent.pos.Z())/tan_theta2 + r_rhoMin.Z(); + plotter->Fill2D("pczguess_vs_pc_int3",180,0,200,150,0,200,pcz_guess_int3,pcevent.pos.Z(),"phicut"); + //plotter->Fill2D("pczguess_vs_pc_int2_a"+std::to_string(pcevent.multi1)+"_c"+std::to_string(pcevent.multi2),180,0,200,150,0,200,pcz_guess_int2,pcevent.pos.Z(),"phicut"); + + + double pcz_guess = pcz_guess_int; + plotter->Fill2D("pctheta_vs_qqqtheta_sv",180,-360,360,180,-360,360,(qqqevent.pos-TVector3(0,0,source_vertex)).Theta()*180/M_PI,(pcevent.pos-TVector3(0,0,source_vertex)).Theta()*180/M_PI,"phicut"); + plotter->Fill2D("pctheta_vs_qqqtheta_rmz",180,-360,360,180,-360,360,(qqqevent.pos-TVector3(0,0,r_rhoMin.Z())).Theta()*180/M_PI,(pcevent.pos-TVector3(0,0,r_rhoMin.Z())).Theta()*180/M_PI,"phicut"); + plotter->Fill2D("pctheta_vs_qqqtheta_rm",180,-360,360,180,-360,360,(qqqevent.pos-r_rhoMin).Theta()*180/M_PI,(pcevent.pos-r_rhoMin).Theta()*180/M_PI,"phicut"); + + plotter->Fill2D("pczguess_vs_pc_phi="+std::to_string(qqqevent.pos.Phi()*180./M_PI),300,0,200,150,0,200,pcz_guess,pcevent.pos.Z(),"phicut"); + + //plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut"); + } + } + }//end PC QQQ coincidence + //HALFTIME! Can stop here in future versions + return kTRUE; + if (anodeHits.size() >= 1 && cathodeHits.size() >= 1) + { + // 2. CRITICAL FIX: Define reference vector 'a' + // In Analyzer.cxx, 'a' was left over from the loop. We use the first anode wire as reference here. + // (Assuming pwinstance.An is populated and wires are generally parallel). + TVector3 refAnode = pwinstance.An[0].first - pwinstance.An[0].second; + + { + for (const auto &anode : anodeHits) + { + aID = anode.first; + aE = anode.second; + aESum += aE; + if (aE > aEMax) + { + aEMax = aE; + aIDMax = aID; + } + } + + for (const auto &cathode : cathodeHits) + { + cID = cathode.first; + cE = cathode.second; + plotter->Fill2D("AnodeMax_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aIDMax, cID, "hRawPC"); + plotter->Fill2D("Anode_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aID, cID, "hRawPC"); + plotter->Fill2D("Anode_vs_CathodeE", 2000, 0, 30000, 2000, 0, 30000, aE, cE, "hGMPC"); + plotter->Fill2D("CathodeMult_V_CathodeE", 6, 0, 6, 2000, 0, 30000, cathodeHits.size(), cE, "hGMPC"); + /*for (int j = -4; j < 3; j++) + { + if ((aIDMax + 24 + j) % 24 == 23 - cID) + { + corrcatMax.push_back(std::pair(cID, cE)); + cESum += cE; + } + }*/ + if((aIDMax + cID)%24 == 22 || (aIDMax + cID)%24==23 || (aIDMax + cID)%24>=0 || (aIDMax + cID)%24<=3 ) { + corrcatMax.push_back(std::pair(cID, cE)); + cESum += cE; + if(cE > cEMax) { + cEMax = cE; + cIDMax = cID; + } + } + } + } + } + + TVector3 anodeIntersection,vector_closest_to_z; + anodeIntersection.Clear(); + vector_closest_to_z.Clear(); + if (corrcatMax.size() > 0) + { + double x = 0, y = 0, z = 0; + for (const auto &corr : corrcatMax) + { + if (pwinstance.Crossover[aIDMax][corr.first][0].z > 9000000) + continue; + if (cESum > 0) + { + x += (corr.second) / cESum * pwinstance.Crossover[aIDMax][corr.first][0].x; + y += (corr.second) / cESum * pwinstance.Crossover[aIDMax][corr.first][0].y; + z += (corr.second) / cESum * pwinstance.Crossover[aIDMax][corr.first][0].z; + } + } + if (x == 0 && y == 0 && z == 0) + ; + // to ignore events with no valid crossover points + else { + anodeIntersection = TVector3(x, y, z); + if(realtime) { + //crossoverg->SetPoint(0,x,y,z); + crossoverg->AddPoint(x,y,z); + } + //std::cout << "Anode Intersection: " << anodeIntersection.X() << ", " << anodeIntersection.Y() << ", " << anodeIntersection.Z() << " " << aIDMax << std::endl; + } + } + bool PCQQQPhiCut = false; + // flip the algorithm for cathode 1 multi anode events + if ((hitPos.Phi() > (anodeIntersection.Phi() - TMath::PiOver4())) && (hitPos.Phi() < (anodeIntersection.Phi() + TMath::PiOver4()))) { + PCQQQPhiCut = true; + } + + if(anodeIndex!=-1 && cathodeIndex !=-1 && hitPos.Perp()!=0 && anodeIntersection.Perp()!=0 && realtime && PCQQQPhiCut && PCQQQTimeCut) { + //can1->Modified(); + //can1->Update(); + TVector3 x2(anodeIntersection); + TVector3 x1(hitPos); + TVector3 v = x2-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + TVector3 r_rhoMin = x1 + t_minimum*v; + + trajectory->SetPoint(0,x1.X(),x1.Y(),x1.Z()); + trajectory->SetPoint(1,r_rhoMin.X(),r_rhoMin.Y(),r_rhoMin.Z()); + + for(auto cath: corrcatMax) { + plc[cath.first]->SetLineWidth(3); + //plc[cath.first]->SetLineStyle(kLine); + } + for(auto anodeW: anodeHits) { + pla[anodeW.first]->SetLineWidth(3); + //pla[anodeW.first]->SetLineStyle(kLine); + } + //can2->Modified(); + //can2->Update(); + //while(can1->WaitPrimitive()); + + //pla[anodeIndex]->SetLineWidth(1); + //pla[anodeIndex]->SetLineStyle(kDotted); + for(auto anodeW: anodeHits) { + pla[anodeW.first]->SetLineWidth(1); + pla[anodeW.first]->SetLineStyle(kDotted); + } + for(auto cath: corrcatMax) { + plc[cathodeIndex]->SetLineStyle(kDotted); + plc[cath.first]->SetLineWidth(1); + } + } + + //for (double Tz = 60; Tz <= 100; Tz += 1.0) + //{ + // TVector3 TargetPos(0, 0, Tz); + //if(PCQQQPhiCut && anodeIntersection.Perp()>0 && anodeIntersection.Z()!=0 && cathodeHits.size()>=2) { + //plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut) + "_TZ" + std::to_string(Tz), 400, 0, 180, 90, 0, 90, (anodeIntersection - TargetPos).Theta() * 180. / TMath::Pi(), (hitPos - TargetPos).Theta() * 180. / TMath::Pi(), "TPosVariation"); + //plotter->Fill2D("R_ratio_to_Z_ratio" + std::to_string(PCQQQTimeCut) + "_TZ" + std::to_string(Tz), 100, -2, 2, 100, -2, 2, (anodeIntersection - TargetPos).Z()/(hitPos-TargetPos).Z(), ((anodeIntersection - TargetPos).Perp()+2.5)/(hitPos-TargetPos).Perp(), "TPosVariation"); + //} + //} + + if (anodeIntersection.Z() != 0 && anodeIntersection.Perp()>0 && HitNonZero) + { + plotter->Fill1D("PC_Z_Projection", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("Z_Proj_VsDelTime", 600, -300, 300, 200, -2000, 2000, anodeIntersection.Z(), anodeT - cathodeT, "hPCzQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi", 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + //plotter->Fill2D("Inttheta_vs_QQQtheta", 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + //plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut)+ "_PC"+std::to_string(PCQQQPhiCut), 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + } + + if(anodeIntersection.Z() !=0 && anodeIntersection.Perp() > 0 && PCSX3TimeCut) { + plotter->Fill1D("PC_Z_Projection_sx3", 600, -200, 200, anodeIntersection.Z(), "hPCZSX3"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() >= 2) + plotter->Fill1D("PC_Z_Projection_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 1) + { + plotter->Fill1D("PC_Z_proj_1C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_1C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill1D("PC_Z_proj_2C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_2C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() > 2) + { + plotter->Fill1D("PC_Z_proj_nC", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_nC", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + plotter->Fill2D("AHits_vs_CHits", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // make another plot with nearest neighbour constraint + bool hasNeighbourAnodes = false; + bool hasNeighbourCathodes = false; + + // 1. Check Anodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < anodeHits.size(); i++) + { + for (size_t j = i + 1; j < anodeHits.size(); j++) + { + int diff = std::abs(anodeHits[i].first - anodeHits[j].first); + if (diff == 1 || diff == 23) + { // 23 handles the cylindrical wrap + hasNeighbourAnodes = true; + break; + } + } + if (hasNeighbourAnodes) + break; + } + + // 2. Check Cathodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < cathodeHits.size(); i++) + { + for (size_t j = i + 1; j < cathodeHits.size(); j++) + { + int diff = std::abs(cathodeHits[i].first - cathodeHits[j].first); + if (diff == 1 || diff == 23) + { + hasNeighbourCathodes = true; + break; + } + } + if (hasNeighbourCathodes) + break; + } + + // --------------------------------------------------------- + // FILL PLOTS + // --------------------------------------------------------- + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + { + plotter->Fill2D("AHits_vs_CHits_NA" + std::to_string(hasNeighbourAnodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + plotter->Fill2D("AHits_vs_CHits_NC" + std::to_string(hasNeighbourCathodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // Constraint Plot: Only fill if BOTH planes have adjacent hits + // This effectively removes events with only isolated single-wire hits (noise) + if (hasNeighbourAnodes && hasNeighbourCathodes) + { + plotter->Fill2D("AHits_vs_CHits_NN", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + } + } + + if (HitNonZero && anodeIntersection.Z() != 0) + { + pw_contr.CalTrack2(hitPos, anodeIntersection); + plotter->Fill1D("VertexRecon", 600, -1300, 1300, pw_contr.GetZ0()); + plotter->Fill1D("VertexRecon_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, pw_contr.GetZ0()); + + if (cathodeHits.size() == 2) + plotter->Fill1D("VertexRecon_2c_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, pw_contr.GetZ0()); + + TVector3 x2(anodeIntersection), x1(hitPos); + + TVector3 v = x2-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + vector_closest_to_z = x1 + t_minimum*v; + + plotter->Fill1D("VertexRecon_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(),"customVertex"); + + if(qqqenergy<4.0) + plotter->Fill1D("VertexRecon_Z(qqqE<4.0MeV)_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(),"customVertex"); + + if(vector_closest_to_z.Perp() < 20) { + plotter->Fill1D("VertexRecon_RadialCut_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(),"customVertex"); + } + + plotter->Fill2D("VertexRecon_XY_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 100,-100,100, vector_closest_to_z.X(), vector_closest_to_z.Y(),"customVertex"); + if(cathodeHits.size()==2) { + plotter->Fill1D("VertexRecon2C_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(),"customVertex"); + if(vector_closest_to_z.Perp() < 20) { + plotter->Fill1D("VertexRecon2C_RadialCut_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(),"customVertex"); + } + plotter->Fill2D("VertexRecon2C_XY_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 100,-100,100, vector_closest_to_z.X(), vector_closest_to_z.Y(),"customVertex"); + plotter->Fill2D("VertexRecon2C_RhoZ_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 600,-1300,1300, vector_closest_to_z.Perp(), vector_closest_to_z.Z(),"customVertex"); + plotter->Fill2D("VertexRecon2C_Z_vs_QQQE_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, 800,0,20, vector_closest_to_z.Z(), qqqenergy,"customVertex"); + } + + } + + for (int i = 0; i < qqq.multi; i++) + { + if(anodeIntersection.Perp() > 0) { //suppress x,y=0,0 events + if (PCQQQTimeCut) { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100,hitPos.X(),hitPos.Y(),"hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + } + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + int qqqID = -1; + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + qqqID = qqq.id[i]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + tRing = static_cast(qqq.t[i]); + eRing = qqq.e[i]; + qqqID = qqq.id[i]; + } + else + continue; + + if (qqqCalibValid[qqq.id[i]][chRing][chWedge]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + } + else + continue; + + // if (anodeIntersection.Z() != 0) + { + plotter->Fill2D("PC_Z_vs_QQQRing", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQRho", 600, -300, 300, 40, 40, 110, anodeIntersection.Z(), hitPos.Perp(), "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill2D("PC_Z_vs_QQQRing_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQRing_2C" + std::to_string(qqq.id[i]), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQWedge_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chWedge, "hPCzQQQ"); + } + plotter->Fill2D("VertexRecon_QQQRingTC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, 16, 0, 16, vector_closest_to_z.Z(), chRing, "hPCQQQ"); + double phi = TMath::ATan2(anodeIntersection.Y(), anodeIntersection.X()) * 180. / TMath::Pi(); + plotter->Fill2D("PolarAngle_Vs_QQQWedge" + std::to_string(qqqID), 360, -360, 360, 16, 0, 16, phi, chWedge, "hPCQQQ"); + // plotter->Fill2D("EdE_PC_vs_QQQ_timegate_ls1000"+std::to_string()) + + plotter->Fill2D("PC_Z_vs_QQQRing_Det" + std::to_string(qqqID), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCQQQ"); + //double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + //double rho = 50. + 40. / 16. * (chRing + 0.5); + + for (int k = 0; k < pc.multi; k++) + { + if(pc.index[k] >= 24) + continue; + +// double sinTheta = TMath::Sin((hitPos-vector_closest_to_z).Theta()); + double sinTheta = TMath::Sin((anodeIntersection-TVector3(0,0,90.0)).Theta()); +// double sinTheta = TMath::Sin((anodeIntersection-vector_closest_to_z).Theta()); +// double sinTheta = TMath::Sin((hitPos-TVector3(0,0,30.0)).Theta()); +// double sinTheta = TMath::Sin(hitPos.Theta()); + + if(cathodeHits.size()==2 && PCQQQPhiCut) { + plotter->Fill2D("CalibratedQQQE_RvsCPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsCPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_RvsPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("PCQQQ_dTimevsdPhi", 200, -2000, 2000, 80, -200, 200, tRing - static_cast(pc.t[k]), (hitPos.Phi()-anodeIntersection.Phi()) * 180. / TMath::Pi(), "hTiming"); + } + + } + }///qqq i==j case end + } //j loop end + } // qqq i loop end + + TVector3 guessVertex(0,0,source_vertex); //for run12, subtract anodeIntersection.Z() by ~74.0 seems to work + //rho=40.0 mm is halfway between the cathodes(rho=42) and anodes(rho=37) +// double pcz_guess = 37.0/TMath::Tan((hitPos-guessVertex).Theta()) + guessVertex.Z(); //this is ideally kept to be all QQQ+userinput for calibration of pcz + double pcz_guess = z_to_crossover_rho(anodeIntersection.Z())/TMath::Tan((hitPos-guessVertex).Theta()) + guessVertex.Z(); //this is ideally kept to be all QQQ+userinput for calibration of pcz + if(PCQQQTimeCut && PCQQQPhiCut && hitPos.Perp()>0 && anodeIntersection.Perp()>0 && cathodeHits.size()>=2) { + plotter->Fill2D("pczguess_vs_qqqE",100,0,200,800,0,20,pcz_guess,qqqenergy,"pczguess"); + double pczoffset=0.0; + //plotter->Fill2D("pczguess_vs_pcz_rad="+std::to_string(hitPos.Perp()),100,0,200,150,0,200,pcz_guess,anodeIntersection.Z(),"pczguess"); //entirely qqq-derived position vs entirely PC derived position + plotter->Fill2D("pczguess_vs_pcz_phi="+std::to_string(hitPos.Phi()*180./M_PI),200,0,200,200,0,200,pcz_guess,anodeIntersection.Z()+pczoffset,"pczguess"); //entirely qqq-derived position vs entirely PC derived position + plotter->Fill2D("pczguess_vs_pcz",200,0,200,200,0,200,pcz_guess,anodeIntersection.Z()+pczoffset); + plotter->Fill2D("pcz_vs_pcPhi_rad="+std::to_string(hitPos.Perp()),360,0,360,150,0,200,anodeIntersection.Phi()*180./M_PI,anodeIntersection.Z()+pczoffset,"pczguess"); + } + for (int i = 0; i < sx3.multi; i++) + { + // plotting sx3 strip hits vs anode phi + if (sx3.ch[i] < 8 && anodeIntersection.Perp()>0) + plotter->Fill2D("PCPhi_vs_SX3Strip", 100, -200, 200, 8 * 24, 0, 8 * 24, anodeIntersection.Phi() * 180. / TMath::Pi(), sx3.id[i] * 8 + sx3.ch[i]); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 3) + { + plotter->Fill1D("PC_Z_proj_3C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + } + + if(anodeIntersection.Perp()!=0) { + plotter->Fill2D("AnodeMaxE_Vs_Cathode_Sum_Energy", 2000, 0, 20000, 2000, 0, 10000, aEMax, cESum, "hGMPC"); + plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy", 800, 0, 20000, 800, 0, 10000, aESum, cEMax, "hGMPC"); + plotter->Fill2D("AnodeMaxE_Vs_Cathode_Max_Energy", 800, 0, 20000, 800, 0, 10000, aEMax, cEMax, "hGMPC"); + //double sinTheta = TMath::Sin((anodeIntersection - TVector3(0,0,source_vertex)).Theta());///TMath::Sin((TVector3(51.5,0,128.) - TVector3(0,0,85)).Theta()); + //plotter->Fill2D("AnodeMaxE_Vs_Cathode_Max_Energy_path_corrected", 800, 0, 20000, 800, 0, 10000, aEMax*sinTheta, cEMax*sinTheta, "hGMPC"); + plotter->Fill2D("AnodeSumE_Vs_Cathode_Sum_Energy", 800, 0, 20000, 800, 0, 10000, aESum, cESum, "hGMPC"); + plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_TC"+std::to_string(PCQQQTimeCut)+"_PC"+std::to_string(PCQQQPhiCut), 800, 0, 20000, 800, 0, 10000, aESum, cEMax, "hGMPC"); + //plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_path_corrected"+std::to_string(PCQQQTimeCut)+"_PC"+std::to_string(PCQQQPhiCut), 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cEMax*sinTheta, "hGMPC"); + //plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_path_corrected", 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cEMax*sinTheta, "hGMPC"); + + if(PCQQQTimeCut && PCQQQPhiCut) { + plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_TC"+std::to_string(PCQQQTimeCut)+"_PC"+std::to_string(PCQQQPhiCut)+"_cMax"+std::to_string(cIDMax), 800, 0, 20000, 800, 0, 10000, aESum, cEMax, "hGMPC"); + } + //plotter->Fill2D("AnodeSumE_Vs_CathodeSum_Energy_path_corrected", 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cESum*sinTheta, "hGMPC"); + //plotter->Fill2D("AnodeSumE_Vs_CathodeSum_Energy_path_corrected_TC"+std::to_string(PCQQQTimeCut)+"_PC"+std::to_string(PCQQQPhiCut), 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cESum*sinTheta, "hGMPC"); */ + } + plotter->Fill1D("Correlated_Cathode_MaxAnode", 6, 0, 5, corrcatMax.size(), "hGMPC"); + plotter->Fill2D("Correlated_Cathode_VS_MaxAnodeEnergy", 6, 0, 5, 2000, 0, 30000, corrcatMax.size(), aEMax, "hGMPC"); + plotter->Fill1D("AnodeHits", 12, 0, 11, anodeHits.size(), "hGMPC"); + plotter->Fill2D("AnodeMaxE_vs_AnodeHits", 12, 0, 11, 2000, 0, 30000, anodeHits.size(), aEMax, "hGMPC"); + + if (anodeHits.size() < 1) + { + plotter->Fill1D("NoAnodeHits_CathodeHits", 6, 0, 5, cathodeHits.size(), "hGMPC"); + } + + for(auto cwevent: cWireEvents) { + //plotter->Fill1D("cwdtqqq_vs_cw"+std::to_string(PCQQQTimeCut),800,-2000,2000,24,0,24,std::get<2>(cwevent)-qqqtimestamp,std::get<0>(cwevent)); + for(auto awevent: aWireEvents) { + plotter->Fill2D("aw_vs_cw",24,0,24,24,0,24,std::get<0>(awevent),std::get<0>(cwevent)); + plotter->Fill2D("aw_vs_cw_dtq"+std::to_string(PCQQQTimeCut),24,0,24,24,0,24,std::get<0>(awevent),std::get<0>(cwevent)); + } + } + for(auto awevent: aWireEvents) { + //plotter->Fill1D("awdtqqq_vs_aw"+std::to_string(PCQQQTimeCut),800,-2000,2000,24,0,24,std::get<2>(awevent)-qqqtimestamp,std::get<0>(awevent)); + } + + + return kTRUE; +} + +void MakeVertex::Terminate() +{ + plotter->FlushToDisk(); +/* can1->Modified(); + can1->Update(); + can2->Modified(); + can2->Update(); + while(can1->WaitPrimitive()); + while(can2->WaitPrimitive());*/ +} diff --git a/anasen_analysis_vignesh/MakeVertex.h b/anasen_analysis_vignesh/MakeVertex.h new file mode 100644 index 0000000..d14bf2e --- /dev/null +++ b/anasen_analysis_vignesh/MakeVertex.h @@ -0,0 +1,144 @@ +#ifndef MakeVertex_h +#define MakeVertex_h + +#include +#include +#include +#include +#include +#include +#include // Required for vectors +#include // Required for std::pair + +#include "Armory/ClassDet.h" +#include "Armory/ClassPW.h" // YOU ADDED THIS (Correct! Defines Coord) + +class MakeVertex : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + Det misc; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + TBranch *b_miscMulti; //! + TBranch *b_miscID; //! + TBranch *b_miscCh; //! + TBranch *b_miscE; //! + TBranch *b_miscT; //! + TBranch *b_miscTf; //! + + + // 2. Persistent Vectors (REQUIRED for the optimized .cxx to work) + std::vector> anodeHits; + std::vector> cathodeHits; + std::vector> corrcatMax; + std::vector> corranoMax; + std::vector cathodeTimes; + std::vector anodeTimes; + + MakeVertex(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~MakeVertex() { } + virtual Int_t Version() const { + return 2; + } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { + return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; + } + virtual void SetOption(const char *option) { + fOption = option; + } + virtual void SetObject(TObject *obj) { + fObject = obj; + } + virtual void SetInputList(TList *input) { + fInput = input; + } + virtual TList *GetOutputList() const { + return fOutput; + } + virtual void SlaveTerminate(); + virtual void Terminate(); + + void MakeAnalysisHistograms(); + void MakeDiagnosticHistograms(); + ClassDef(MakeVertex,0); +}; + +#endif + +#ifdef MakeVertex_cxx +void MakeVertex::Init(TTree *tree) { + + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + /*fChain->SetBranchAddress("miscMulti", &misc.multi, &b_miscMulti); + fChain->SetBranchAddress("miscID", &misc.id, &b_miscID); + fChain->SetBranchAddress("miscCh", &misc.ch, &b_miscCh); + fChain->SetBranchAddress("miscE", &misc.e, &b_miscE); + fChain->SetBranchAddress("miscT", &misc.t, &b_miscT);*/ +} + +Bool_t MakeVertex::Notify() { + return kTRUE; +} + +void MakeVertex::SlaveBegin(TTree * /*tree*/) { + // TString option = GetOption(); +} + +void MakeVertex::SlaveTerminate() { +} +#endif // #ifdef MakeVertex_cxx diff --git a/anasen_analysis_vignesh/MakeVertexSX3.C b/anasen_analysis_vignesh/MakeVertexSX3.C new file mode 100644 index 0000000..c468879 --- /dev/null +++ b/anasen_analysis_vignesh/MakeVertexSX3.C @@ -0,0 +1,958 @@ +#define MakeVertexSX3_cxx + +#include "MakeVertexSX3.h" +#include "Armory/ClassPW.h" +#include "Armory/HistPlotter.h" +#include "Armory/SX3Geom.h" + +#include +#include +#include +#include +#include +#include "TVector3.h" + +#include +#include +#include +#include +#include +#include +#include +#include + +// Global instances +PW pw_contr; +PW pwinstance; +TVector3 hitPos; +double qqqenergy, qqqtimestamp; +class Event { +public: + Event(TVector3 p, double e1, double e2, double t1, double t2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2) {} + Event(TVector3 p, double e1, double e2, double t1, double t2, int c1, int c2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2), ch1(c1), ch2(c2) {} + + TVector3 pos; + int ch1=-1; //int(ch1/16) gives qqq id, ch1%16 gives ring# + int ch2=-1; //int(ch2/16) gives qqq id, ch2%16 gives wedge# + double Energy1=-1; //Front for QQQ, Anode for PC + double Energy2=-1; //Back for QQQ, Cathode for PC + double Time1=-1; + double Time2=-1; + +}; + +// Calibration globals +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +// TCutg *cutQQQ; + +double sx3BackGain[24][4][4] = {{{1.}}}; +double sx3FrontGain[24][4] = {{1.}}; +double sx3FrontOffset[24][4] = {{0.}}; +double sx3RightGain[24][4] = {{1.}}; + +// PC Arrays +double pcSlope[48]; +double pcIntercept[48]; + +HistPlotter *plotter; + +bool HitNonZero; +bool sx3ecut; +bool qqqEcut; + +void MakeVertexSX3::Begin(TTree * /*tree*/) +{ + TString option = GetOption(); + plotter = new HistPlotter("Analyzer_SX3.root", "TFILE"); + pw_contr.ConstructGeo(); + pwinstance.ConstructGeo(); + + // --------------------------------------------------------- + // 1. CRITICAL FIX: Initialize PC Arrays to Default (Raw) + // --------------------------------------------------------- + for (int i = 0; i < 48; i++) + { + pcSlope[i] = 1.0; // Default slope = 1 (preserves Raw energy) + pcIntercept[i] = 0.0; // Default intercept = 0 + } + + // Calculate Crossover Geometry ONCE + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha; + + for (size_t i = 0; i < pwinstance.An.size(); i++) + { + a = pwinstance.An[i].first - pwinstance.An[i].second; + + for (size_t j = 0; j < pwinstance.Ca.size(); j++) + { + c = pwinstance.Ca[j].first - pwinstance.Ca[j].second; + diff = pwinstance.An[i].first - pwinstance.Ca[j].first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + + Crossover[i][j][0].x = pwinstance.An[i].first.X() + alpha * a.X(); + Crossover[i][j][0].y = pwinstance.An[i].first.Y() + alpha * a.Y(); + Crossover[i][j][0].z = pwinstance.An[i].first.Z() + alpha * a.Z(); + + if (Crossover[i][j][0].z < -190 || Crossover[i][j][0].z > 190 || (i+j)%24 == 12) + { + Crossover[i][j][0].z = 9999999; + } + + Crossover[i][j][1].x = alpha; + Crossover[i][j][1].y = 0; + } + } + + // Load PC Calibrations + std::ifstream inputFile("slope_intercept_results.txt"); + if (inputFile.is_open()) + { + std::string line; + int index; + double slope, intercept; + while (std::getline(inputFile, line)) + { + std::stringstream ss(line); + ss >> index >> slope >> intercept; + if (index >= 0 && index <= 47) + { + pcSlope[index] = slope; + pcIntercept[index] = intercept; + } + } + inputFile.close(); + } + else + { + std::cerr << "Error opening slope_intercept.txt" << std::endl; + } + + // Load QQQ Cuts from file + // { + // std::string filename = "QQQ_PCCut.root"; + // TFile *cutFile = TFile::Open(filename.c_str(), "READ"); + // if (cutFile && !cutFile->IsZombie()) + // { + // cutQQQ = (TCutg *)cutFile->Get("cutQQQPC"); + // if (cutQQQ) + // { + // std::cout << "Loaded QQQ PC cut from " << filename << std::endl; + // } + // else + // { + // std::cerr << "Error: cutQQQPC not found in " << filename << std::endl; + // } + // cutFile->Close(); + // } + // } + + // ... (Load QQQ Gains and Calibs - same as before) ... + { + std::string filename = "qqq_GainMatch.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double gainw, gainr; + while (infile >> det >> wedge >> ring >> gainw >> gainr) + { + qqqGain[det][wedge][ring] = gainw; + qqqGainValid[det][wedge][ring] = (gainw > 0); + // std::cout << "QQQ Gain Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " GainW " << gainw << " GainR " << gainr << std::endl; + } + infile.close(); + } + } + { + std::string filename = "qqq_Calib.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double slope; + while (infile >> det >> wedge >> ring >> slope) + { + qqqCalib[det][wedge][ring] = slope; + qqqCalibValid[det][wedge][ring] = (slope > 0); + // std::cout << "QQQ Calib Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " Slope " << slope << std::endl; + } + infile.close(); + } + } + + { + std::ifstream infile("sx3cal/backgains.dat"); + std::string temp; + int backpos, frontpos, clkpos; + std::cout << "foo" << std::endl; + if (infile.is_open()) + while(infile>>clkpos>>temp>>frontpos>>temp>>backpos>>sx3BackGain[clkpos][frontpos][backpos]) + std::cout << sx3BackGain[clkpos][frontpos][backpos] << std::endl; + infile.close(); + + infile.open("sx3cal/frontgains.dat"); + if (infile.is_open()) + while(infile>>clkpos>>temp>>temp>>frontpos>>sx3FrontOffset[clkpos][frontpos]>>sx3FrontGain[clkpos][frontpos]) + std::cout << sx3FrontOffset[clkpos][frontpos] << " " << sx3FrontGain[clkpos][frontpos] << std::endl; + infile.close(); + + infile.open("sx3cal/rightgains.dat"); + if (infile.is_open()) + while(infile>>clkpos>>frontpos>>temp>>sx3RightGain[clkpos][frontpos]) { + sx3RightGain[clkpos][frontpos]=TMath::Abs(sx3RightGain[clkpos][frontpos]); + } + infile.close(); + + } + std::cout << "aaa" << std::endl; +} + +Bool_t MakeVertexSX3::Process(Long64_t entry) +{ + hitPos.Clear(); + qqqenergy = -1; + qqqtimestamp=-1; + HitNonZero = false; + bool qqq1000cut = false; + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + std::vector sx3Events; + if(sx3.multi>1) { + std::array Fsx3; + //std::cout << "-----" << std::endl; + for(int i=0; i=12) continue; + int id = sx3.id[i]; + if(sx3.ch[i]>=8) { + int sx3ch=sx3.ch[i]-8; + sx3ch=(sx3ch+3)%4; + if(sx3ch==0 || sx3ch==3) continue; + float value=sx3.e[i]; + int gch = sx3.id[i]*4+(sx3.ch[i]-8); + Fsx3.at(id).fillevent("BACK",sx3ch,value); + Fsx3.at(id).ts = static_cast(sx3.t[i]); + plotter->Fill2D("sx3backs_raw",100,0,100,800,0,4096,gch,sx3.e[i]); + } else { + int sx3ch=sx3.ch[i]/2; + double value=sx3.e[i]; + if(sx3.ch[i]%2==0) { + Fsx3.at(id).fillevent("FRONT_L",sx3ch,value*sx3RightGain[id][sx3ch]); + } else { + Fsx3.at(id).fillevent("FRONT_R",sx3ch,value); + } + } + } + for(int id=0; id<12; id++) { + Fsx3.at(id).validate(); + auto det = Fsx3.at(id); + bool no_charge_sharing_strict = det.valid_front_chans.size()==1 && det.valid_back_chans.size()==1; + if(det.valid) { + //std::cout << det.frontEL << " " << det.frontEL*sx3RightGain[id][det.stripF] << std::endl; + plotter->Fill2D("be_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF)+"_b"+std::to_string(det.stripB),200,-1,1,800,0,8192, + det.frontX,det.backE,"evsx"); + //std::cout << sx3BackGain[id][det.stripF][det.stripB] << " " << sx3FrontGain[id][det.stripF] << std::endl; + plotter->Fill2D("matched_be_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF),200,-30,30,800,0,8192, + det.frontX*sx3FrontGain[id][det.stripF]+sx3FrontOffset[id][det.stripF],det.backE*sx3BackGain[id][det.stripF][det.stripB],"evsx_matched"); + //plotter->Fill2D("fe_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF)+"_"+std::to_string(det.stripB),200,-1,1,800,0,4096,det.frontX,det.backE,"evsx"); + plotter->Fill2D("l_vs_r_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF),800,0,4096,800,0,4096,det.frontEL,det.frontER,"l_vs_r"); + } + if(det.valid && (id ==9 || id==7 || id == 1 || id==3) && det.stripF!=DEFAULT_NULL && det.stripB!=DEFAULT_NULL) { + double z = det.frontX*sx3FrontGain[id][det.stripF]+sx3FrontOffset[id][det.stripF]; + double backE = det.backE*sx3BackGain[id][det.stripF][det.stripB]; + Event sx3ev(TVector3(0,0,z),backE,-1,det.ts,-1,det.stripB+4*id,det.stripF+4*id); + sx3Events.push_back(sx3ev); + } + } + } + //return kTRUE; + // QQQ Processing + + int qqqCount = 0; + int qqqAdjCh = 0; + // REMOVE WHEN RERUNNING USING THE NEW CALIBRATION FILE + for (int i = 0; i < qqq.multi; i++) + { + //if ((qqq.id[i] == 3 || qqq.id[i] == 1) && qqq.ch[i] < 16) + if (qqq.id[i] == 1 && qqq.ch[i] < 16) //for run 12, 26Al + { + qqq.ch[i] = 16 - qqq.ch[i]; + } + } + for (int i = 0; i < qqq.multi; i++) + { + if (qqq.id[i] == 0 && qqq.ch[i] >= 16) + { + qqq.ch[i] = 31 - qqq.ch[i] + 16; + } + } + + std::vector QQQ_Events, PC_Events; + std::vector QQQ_Events_Raw, PC_Events_Raw; + std::vector QQQ_Events2; //clustering done + + std::unordered_map> qvecr[4], qvecw[4]; + if(qqq.multi>1) { + //if(qqq.multi>=3) std::cout << "-----" << std::endl; + for(int i=0; i=3) std::cout << std::setprecision(16) << "qqq"<< qqq.id[i] << " " << std::string(qqq.ch[i]/16?"ring":"wedge") << qqq.ch[i]%16 << " " << qqq.e[i] << " " << qqq.t[i] - qqq.t[0] << std::endl; + if(qqq.ch[i]/16) { + if(qvecr[qqq.id[i]].find(qqq.ch[i])!=qvecr[qqq.id[i]].end()) std::cout << "mayday!" << std::endl; + qvecr[qqq.id[i]][qqq.ch[i]] = std::tuple(qqq.id[i],qqq.ch[i],qqq.e[i],qqq.t[i]); + } else { + if(qvecw[qqq.id[i]].find(qqq.ch[i])!=qvecw[qqq.id[i]].end()) std::cout << "mayday!" << std::endl; + qvecw[qqq.id[i]][qqq.ch[i]] = std::tuple(qqq.id[i],qqq.ch[i],qqq.e[i],qqq.t[i]); + } + } + } + + bool PCQQQTimeCut = false; + for (int i = 0; i < qqq.multi; i++) { + plotter->Fill2D("QQQ_Index_Vs_Energy", 16 * 8, 0, 16 * 8, 2000, 0, 16000, qqq.index[i], qqq.e[i], "hRawQQQ"); + + for (int j = 0; j < qqq.multi; j++) { + if (j == i) + continue; + plotter->Fill2D("QQQ_Coincidence_Matrix", 16 * 8, 0, 16 * 8, 16 * 8, 0, 16 * 8, qqq.index[i], qqq.index[j], "hRawQQQ"); + } + + for (int k = 0; k < pc.multi; k++) { + if (pc.index[k] < 24 && pc.e[k] > 50) { + plotter->Fill2D("QQQ_Vs_Anode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + plotter->Fill2D("QQQ_Vs_PC_Index", 16 * 8, 0, 16 * 8, 24, 0, 24, qqq.index[i], pc.index[k], "hRawQQQ"); + } + else if (pc.index[k] >= 24 && pc.e[k] > 50) { + plotter->Fill2D("QQQ_Vs_Cathode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + } + } + + for (int j = i + 1; j < qqq.multi; j++) { + if (qqq.id[i] == qqq.id[j]) { + qqqCount++; + + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + double tWedge = 0.0; + + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + tWedge = static_cast(qqq.t[i]); + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i]; + tRing = static_cast(qqq.t[i]); + tWedge = static_cast(qqq.t[j]); + } + else + continue; + + plotter->Fill1D("Wedgetime_Vs_Ringtime", 100, -1000, 1000, tWedge - tRing, "hTiming"); + plotter->Fill2D("RingE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chRing + qqq.id[i] * 16, eRing, "hRawQQQ"); + plotter->Fill2D("WedgeE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chWedge + qqq.id[i] * 16, eWedge, "hRawQQQ"); + + if (qqqCalibValid[qqq.id[i]][chWedge][chRing]) { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + + if(eRingMeV/eWedgeMeV > 3.0 || eRingMeV/eWedgeMeV<1.0/3.0) continue; + //if(eRingMeV<4.0 || eWedgeMeV<4.0) continue; + + double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?" + //z used to be 75+30+23=128 + //we found a 12mm shift towards the vertex later --> 116 + Event qqqevent(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),116), eRingMeV, eWedgeMeV, tRing, tWedge,chRing+qqq.id[i]*16, chWedge+qqq.id[i]*16); + Event qqqeventr(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),116), eRing, eWedge, tRing, tWedge,chRing+qqq.id[i]*16, chWedge+qqq.id[i]*16); + QQQ_Events.push_back(qqqevent); + QQQ_Events_Raw.push_back(qqqeventr); + plotter->Fill2D("QQQCartesianPlot", 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + plotter->Fill2D("QQQCartesianPlot" + std::to_string(qqq.id[i]), 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + if (PCQQQTimeCut) { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ"); + } + else + continue; + + plotter->Fill2D("WedgeE_Vs_RingECal", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ"); + plotter->Fill2D("WedgeE_Vs_RingECal_selected", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ"); + + for (int k = 0; k < pc.multi; k++) + { + plotter->Fill2D("RingCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index" + std::to_string(qqq.id[i]), 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k]); + plotter->Fill2D("RingCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + + if (pc.index[k] < 24 && pc.e[k] > 50) + { + plotter->Fill2D("Timing_Difference_QQQ_PC", 500, -2000, 2000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + plotter->Fill2D("DelT_Vs_QQQRingECal", 500, -2000, 2000, 1000, 0, 10, tRing - static_cast(pc.t[k]), eRingMeV, "hTiming"); + plotter->Fill2D("CalibratedQQQEvsPCE_R", 1000, 0, 10, 2000, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("CalibratedQQQEvsPCE_W", 1000, 0, 10, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ"); + if (tRing - static_cast(pc.t[k]) < -150) // proton tests, 27Al + //if (tRing - static_cast(pc.t[k]) < -150 && tRing - static_cast(pc.t[k]) > -450) // 27Al + //if (tRing - static_cast(pc.t[k]) < -70 && tRing - static_cast(pc.t[k]) > -150) // 17F + { + PCQQQTimeCut = true; + } + } + + if (pc.index[k] >= 24 && pc.e[k] > 50) { + plotter->Fill2D("Timing_Difference_QQQ_PC_Cathode", 500, -2000, 2000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + } + } //end of pc k loop + + if (!HitNonZero) { + double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?" + double x = rho * TMath::Cos(theta); + double y = rho * TMath::Sin(theta); + hitPos.SetXYZ(x, y, (23 + 75 + 30)); + qqqenergy = eRingMeV; + qqqtimestamp = tRing; + HitNonZero = true; + } + } // if j==i + } //j loop end + } //i loop end + + plotter->Fill1D("QQQ_Multiplicity", 10, 0, 10, qqqCount, "hRawQQQ"); + + /*if(QQQ_Events.size()>=1) { + std::cout<< " ---->" << std::endl; + for(auto qe: QQQ_Events) { + std::cout << qe.ch1/16 << " " <> WireEvent; //this stores nearest neighbour wire events, or a 'cluster' + WireEvent aWireEvents, cWireEvents; //naming for book keeping + aWireEvents.clear(); + aWireEvents.reserve(24); + + // PC Gain Matching and Filling + double anodeT = -99999; + double cathodeT = 99999; + int anodeIndex = -1; + int cathodeIndex = -1; + for (int i = 0; i < pc.multi; i++) + { + if (pc.e[i] > 50) + { + plotter->Fill2D("PC_Index_Vs_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], static_cast(pc.e[i]), "hRawPC"); + } else { + continue; + } + + if (pc.index[i] < 48) + { + pc.e[i] = pcSlope[pc.index[i]] * pc.e[i] + pcIntercept[pc.index[i]]; + plotter->Fill2D("PC_Index_VS_GainMatched_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], pc.e[i], "hGMPC"); + } + + if (pc.index[i] < 24) + { + anodeT = static_cast(pc.t[i]); + anodeIndex = pc.index[i]; + aWireEvents[pc.index[i]] = std::tuple(pc.index[i],pc.e[i],static_cast(pc.t[i])); + } + else + { + cathodeT = static_cast(pc.t[i]); + cathodeIndex = pc.index[i] - 24; + cWireEvents[pc.index[i]-24] = std::tuple(pc.index[i]-24,pc.e[i],static_cast(pc.t[i])); + } + + if (anodeT != -99999 && cathodeT != 99999) + { + for (int j = 0; j < qqq.multi; j++) + { + plotter->Fill1D("PC_Time_qqq", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + plotter->Fill2D("PC_Time_Vs_QQQ_ch", 200, -2000, 2000, 16 * 8, 0, 16 * 8, anodeT - cathodeT, qqq.ch[j], "hTiming"); + plotter->Fill2D("PC_Time_vs_AIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, anodeIndex, "hTiming"); + plotter->Fill2D("PC_Time_vs_CIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, cathodeIndex, "hTiming"); + // plotter->Fill1D("PC_Time_A" + std::to_string(anodeIndex) + "_C" + std::to_string(cathodeIndex), 200, -1000, 1000, anodeT - cathodeT, "TimingPC"); + } + + for (int j = 0; j < sx3.multi; j++) + { + plotter->Fill1D("PC_Time_sx3", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + + plotter->Fill1D("PC_Time", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + + for (int j = i + 1; j < pc.multi; j++) + { + plotter->Fill2D("PC_Coincidence_Matrix", 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("PC_Coincidence_Matrix_anodeMinusCathode_lt_-200_" + std::to_string(anodeT - cathodeT < -200), 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("Anode_V_Anode", 24, 0, 24, 24, 0, 24, pc.index[i], pc.index[j], "hGMPC"); + } + } + + anodeHits.clear(); + cathodeHits.clear(); + corrcatMax.clear(); + + int aID = 0; + int cID = 0; + double aE = 0; + double cE = 0; + double aESum = 0; + double cESum = 0; + double aEMax = 0; + int aIDMax = 0; + + + + for (int i = 0; i < pc.multi; i++) { + // if (pc.e[i] > 100) + { + if (pc.index[i] < 24) { + anodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + } + else if (pc.index[i] >= 24) { + cathodeHits.push_back(std::pair(pc.index[i] - 24, pc.e[i])); + } + } + } + + std::sort(anodeHits.begin(),anodeHits.end(),[](std::pair a, std::pair b){ return a.first < b.first;}); + std::sort(cathodeHits.begin(),cathodeHits.end(),[](std::pair a, std::pair b){ return a.first < b.first;}); + + //clusters = collection of (collection of wires) where each wire is (index, energy, timestamp) + std::vector>> aClusters = pwinstance.Make_Clusters(aWireEvents); + std::vector>> cClusters = pwinstance.Make_Clusters(cWireEvents); + + std::vector> sumE_AC; + for(auto aCluster: aClusters) { + for(auto cCluster: cClusters) { + if(aCluster.size()<=1 && cCluster.size()<=1) continue; + auto [crossover,alpha,apSumE,cpSumE,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE] = pwinstance.FindCrossoverProperties(aCluster, cCluster); + if(alpha!=9999999 && apSumE!=-1) { + //Event PCEvent(crossover,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE); + //Event PCEvent(crossover,apSumE,cpSumE,apTSMaxE,cpTSMaxE); + Event PCEvent(crossover,apSumE,cpMaxE,apTSMaxE,cpTSMaxE); //run12 shows cathode-max and anode-sum provide best dE signals. + //std::cout << apSumE << " " << crossover.Perp() << " " << apMaxE << " " << apTSMaxE << std::endl; + PC_Events.push_back(PCEvent); + sumE_AC.push_back(std::pair(apSumE,cpSumE)); + } + } + } + if(QQQ_Events.size() && PC_Events.size()) + plotter->Fill2D("PCEv_vs_QQQEv",20,0,20,20,0,20,QQQ_Events.size(),PC_Events.size()); + + for(auto pcevent:PC_Events) { + for(auto sx3event:sx3Events) { + plotter->Fill1D("dt_pcA_sx3B"+std::to_string(sx3event.ch2),640,-2000,2000,sx3event.Time1 - pcevent.Time1); + plotter->Fill1D("dt_pcC_sx3B"+std::to_string(sx3event.ch2),640,-2000,2000,sx3event.Time1 - pcevent.Time2); + plotter->Fill2D("dE_E_Anodesx3B",400,0,10,800,0,40000,sx3event.Energy1*0.001,pcevent.Energy1); + + plotter->Fill2D("dE_E_Cathodesx3B",400,0,10,800,0,10000,sx3event.Energy1*0.001,pcevent.Energy2); + double sx3z = sx3event.pos.Z()+(75.0/2.0)+23.0-90.0; //w.r.t target origin at 90 for run12 + double sx3rho = 88.0; + double sx3theta = TMath::ATan2(sx3rho,sx3z); + double pczguess = 40.0/TMath::Tan(sx3theta) + 90.0; + plotter->Fill2D("pcz_vs_sx3pczguess",300,0,200,150,0,200,pczguess,pcevent.pos.Z()); + plotter->Fill2D("pcz_vs_sx3pczguess"+std::to_string(sx3event.ch2),300,0,200,150,0,200,pczguess,pcevent.pos.Z()); + plotter->Fill2D("pcz_vs_sx3z",300,0,200,150,0,200,sx3z+90,pcevent.pos.Z()); + } + } + + for(auto pcevent: PC_Events) { + for(auto qqqevent: QQQ_Events) { + plotter->Fill1D("dt_pcA_qqqR",640,-2000,2000,qqqevent.Time1 - pcevent.Time1); + plotter->Fill1D("dt_pcC_qqqW",640,-2000,2000,qqqevent.Time2 - pcevent.Time2); + plotter->Fill2D("dE_E_AnodeQQQR",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1); + plotter->Fill2D("dE_E_CathodeQQQR",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2); + double sinTheta = TMath::Sin((qqqevent.pos - TVector3(0,0,90)).Theta())/TMath::Sin((TVector3(51.5,0,128.) - TVector3(0,0,90)).Theta()); + plotter->Fill2D("dE2_E_AnodeQQQR",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta); + plotter->Fill2D("dE2_E_CathodeQQQR",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2*sinTheta); + + if(qqqevent.pos.Phi() <= pcevent.pos.Phi()+TMath::Pi()/4. && qqqevent.pos.Phi() >= pcevent.pos.Phi()-TMath::Pi()/4.) { + plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut"); + double pcz_guess = 40.0/TMath::Tan((qqqevent.pos-TVector3(0,0,90)).Theta()) + 90; //this is ideally kept to be all QQQ+userinput for calibration of pcz + plotter->Fill2D("pczguess_vs_pc",300,0,200,150,0,200,pcz_guess,pcevent.pos.Z(),"phicut"); + plotter->Fill2D("pczguess_vs_pc_phi="+std::to_string(qqqevent.pos.Phi()*180./M_PI),300,0,200,150,0,200,pcz_guess,pcevent.pos.Z(),"phicut"); + //plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut"); + } + } + } + //HALFTIME! Can stop here in future versions + //return kTRUE; + + if (anodeHits.size() >= 1 && cathodeHits.size() >= 1) + { + // 2. CRITICAL FIX: Define reference vector 'a' + // In Analyzer.cxx, 'a' was left over from the loop. We use the first anode wire as reference here. + // (Assuming pwinstance.An is populated and wires are generally parallel). + TVector3 refAnode = pwinstance.An[0].first - pwinstance.An[0].second; + + { + for (const auto &anode : anodeHits) + { + aID = anode.first; + aE = anode.second; + aESum += aE; + if (aE > aEMax) + { + aEMax = aE; + aIDMax = aID; + } + } + + for (const auto &cathode : cathodeHits) + { + cID = cathode.first; + cE = cathode.second; + plotter->Fill2D("AnodeMax_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aIDMax, cID, "hRawPC"); + plotter->Fill2D("Anode_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aID, cID, "hRawPC"); + plotter->Fill2D("Anode_vs_CathodeE", 2000, 0, 30000, 2000, 0, 30000, aE, cE, "hGMPC"); + plotter->Fill2D("CathodeMult_V_CathodeE", 6, 0, 6, 2000, 0, 30000, cathodeHits.size(), cE, "hGMPC"); + for (int j = -4; j < 3; j++) + { + if ((aIDMax + 24 + j) % 24 == 23 - cID) + { + corrcatMax.push_back(std::pair(cID, cE)); + cESum += cE; + } + } + } + } + } + + TVector3 anodeIntersection,vector_closest_to_z; + anodeIntersection.Clear(); + vector_closest_to_z.Clear(); + if (corrcatMax.size() > 0) + { + double x = 0, y = 0, z = 0; + for (const auto &corr : corrcatMax) + { + if (Crossover[aIDMax][corr.first][0].z > 9000000) + continue; + if (cESum > 0) + { + x += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].x; + y += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].y; + z += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].z; + } + } + if (x == 0 && y == 0 && z == 0) + ; + // to ignore events with no valid crossover points + else + anodeIntersection = TVector3(x, y, z); + // << "Anode Intersection: " << anodeIntersection.X() << ", " << anodeIntersection.Y() << ", " << anodeIntersection.Z() << std::endl; + } + bool PCQQQPhiCut = false; + // flip the algorithm for cathode 1 multi anode events + if ((hitPos.Phi() > (anodeIntersection.Phi() - TMath::PiOver4())) && (hitPos.Phi() < (anodeIntersection.Phi() + TMath::PiOver4()))) { + PCQQQPhiCut = true; + } + + for (double Tz = 60; Tz <= 100; Tz += 1.0) + { + TVector3 TargetPos(0, 0, Tz); + if(PCQQQPhiCut && anodeIntersection.Perp()>0 && anodeIntersection.Z()!=0 && cathodeHits.size()>=2) { + plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut) + "_TZ" + std::to_string(Tz), 400, 0, 180, 90, 0, 90, (anodeIntersection - TargetPos).Theta() * 180. / TMath::Pi(), (hitPos - TargetPos).Theta() * 180. / TMath::Pi(), "TPosVariation"); + //plotter->Fill2D("R_ratio_to_Z_ratio" + std::to_string(PCQQQTimeCut) + "_TZ" + std::to_string(Tz), 100, -2, 2, 100, -2, 2, (anodeIntersection - TargetPos).Z()/(hitPos-TargetPos).Z(), ((anodeIntersection - TargetPos).Perp()+2.5)/(hitPos-TargetPos).Perp(), "TPosVariation"); + } + } + + if (anodeIntersection.Z() != 0 && anodeIntersection.Perp()>0 && HitNonZero) + { + plotter->Fill1D("PC_Z_Projection", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("Z_Proj_VsDelTime", 600, -300, 300, 200, -2000, 2000, anodeIntersection.Z(), anodeT - cathodeT, "hPCzQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi", 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + //plotter->Fill2D("Inttheta_vs_QQQtheta", 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + //plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut)+ "_PC"+std::to_string(PCQQQPhiCut), 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() >= 2) + plotter->Fill1D("PC_Z_Projection_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 1) + { + plotter->Fill1D("PC_Z_proj_1C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_1C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill1D("PC_Z_proj_2C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_2C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() > 2) + { + plotter->Fill1D("PC_Z_proj_nC", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_nC", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + plotter->Fill2D("AHits_vs_CHits", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // make another plot with nearest neighbour constraint + bool hasNeighbourAnodes = false; + bool hasNeighbourCathodes = false; + + // 1. Check Anodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < anodeHits.size(); i++) + { + for (size_t j = i + 1; j < anodeHits.size(); j++) + { + int diff = std::abs(anodeHits[i].first - anodeHits[j].first); + if (diff == 1 || diff == 23) + { // 23 handles the cylindrical wrap + hasNeighbourAnodes = true; + break; + } + } + if (hasNeighbourAnodes) + break; + } + + // 2. Check Cathodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < cathodeHits.size(); i++) + { + for (size_t j = i + 1; j < cathodeHits.size(); j++) + { + int diff = std::abs(cathodeHits[i].first - cathodeHits[j].first); + if (diff == 1 || diff == 23) + { + hasNeighbourCathodes = true; + break; + } + } + if (hasNeighbourCathodes) + break; + } + + // --------------------------------------------------------- + // FILL PLOTS + // --------------------------------------------------------- + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + { + plotter->Fill2D("AHits_vs_CHits_NA" + std::to_string(hasNeighbourAnodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + plotter->Fill2D("AHits_vs_CHits_NC" + std::to_string(hasNeighbourCathodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // Constraint Plot: Only fill if BOTH planes have adjacent hits + // This effectively removes events with only isolated single-wire hits (noise) + if (hasNeighbourAnodes && hasNeighbourCathodes) + { + plotter->Fill2D("AHits_vs_CHits_NN", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + } + } + + if (HitNonZero && anodeIntersection.Z() != 0) + { + pw_contr.CalTrack2(hitPos, anodeIntersection); + plotter->Fill1D("VertexRecon", 600, -1300, 1300, pw_contr.GetZ0()); + plotter->Fill1D("VertexRecon_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, pw_contr.GetZ0()); + + if (cathodeHits.size() == 2) + plotter->Fill1D("VertexRecon_2c_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, pw_contr.GetZ0()); + + TVector3 x2(anodeIntersection), x1(hitPos); + + TVector3 v = x2-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + vector_closest_to_z = x1 + t_minimum*v; + + plotter->Fill1D("VertexRecon_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + if(vector_closest_to_z.Perp() < 20) { + plotter->Fill1D("VertexRecon_RadialCut_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + } + + plotter->Fill2D("VertexRecon_XY_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 100,-100,100, vector_closest_to_z.X(), vector_closest_to_z.Y() ,"customVertex"); + if(cathodeHits.size()==2) { + plotter->Fill1D("VertexRecon2C_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + if(vector_closest_to_z.Perp() < 20) { + plotter->Fill1D("VertexRecon2C_RadialCut_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + } + plotter->Fill2D("VertexRecon2C_XY_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 100,-100,100, vector_closest_to_z.X(), vector_closest_to_z.Y() ,"customVertex"); + plotter->Fill2D("VertexRecon2C_RhoZ_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 600,-1300,1300, vector_closest_to_z.Perp(), vector_closest_to_z.Z() ,"customVertex"); + plotter->Fill2D("VertexRecon2C_Z_vs_QQQE_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, 800,0,20000, vector_closest_to_z.Z(), qqqenergy ,"customVertex"); + } + + } + + for (int i = 0; i < qqq.multi; i++) + { + if(anodeIntersection.Perp() > 0) { //suppress x,y=0,0 events + if (PCQQQTimeCut) { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + } + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + int qqqID = -1; + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + qqqID = qqq.id[i]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + tRing = static_cast(qqq.t[i]); + eRing = qqq.e[i]; + qqqID = qqq.id[i]; + } + else + continue; + + if (qqqCalibValid[qqq.id[i]][chRing][chWedge]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + } + else + continue; + + // if (anodeIntersection.Z() != 0) + { + plotter->Fill2D("PC_Z_vs_QQQRing", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill2D("PC_Z_vs_QQQRing_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQRing_2C" + std::to_string(qqq.id[i]), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQWedge_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chWedge, "hPCzQQQ"); + } + plotter->Fill2D("VertexRecon_QQQRingTC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, 16, 0, 16, vector_closest_to_z.Z(), chRing, "hPCQQQ"); + double phi = TMath::ATan2(anodeIntersection.Y(), anodeIntersection.X()) * 180. / TMath::Pi(); + plotter->Fill2D("PolarAngle_Vs_QQQWedge" + std::to_string(qqqID), 360, -360, 360, 16, 0, 16, phi, chWedge, "hPCQQQ"); + // plotter->Fill2D("EdE_PC_vs_QQQ_timegate_ls1000"+std::to_string()) + + plotter->Fill2D("PC_Z_vs_QQQRing_Det" + std::to_string(qqqID), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCQQQ"); + //double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + //double rho = 50. + 40. / 16. * (chRing + 0.5); + + for (int k = 0; k < pc.multi; k++) + { + if(pc.index[k] >= 24) + continue; + +// double sinTheta = TMath::Sin((hitPos-vector_closest_to_z).Theta()); + double sinTheta = TMath::Sin((anodeIntersection-TVector3(0,0,90.0)).Theta()); +// double sinTheta = TMath::Sin((anodeIntersection-vector_closest_to_z).Theta()); +// double sinTheta = TMath::Sin((hitPos-TVector3(0,0,30.0)).Theta()); +// double sinTheta = TMath::Sin(hitPos.Theta()); + + if(cathodeHits.size()==2 && PCQQQPhiCut) { + plotter->Fill2D("CalibratedQQQE_RvsCPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsCPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_RvsPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("PCQQQ_dTimevsdPhi", 200, -2000, 2000, 80, -200, 200, tRing - static_cast(pc.t[k]), (hitPos.Phi()-anodeIntersection.Phi()) * 180. / TMath::Pi(), "hTiming"); + } + + } + }///qqq i==j case end + } //j loop end + } // qqq i loop end + + TVector3 guessVertex(0,0,90.); //for run12, subtract anodeIntersection.Z() by ~74.0 seems to work + //rho=40.0 mm is halfway between the cathodes(rho=42) and anodes(rho=37) + double pcz_guess = 42.0/TMath::Tan((hitPos-guessVertex).Theta()) + guessVertex.Z(); //this is ideally kept to be all QQQ+userinput for calibration of pcz + if(PCQQQTimeCut && PCQQQPhiCut && hitPos.Perp()>0 && anodeIntersection.Perp()>0 && cathodeHits.size()>=2) { + plotter->Fill2D("pczguess_vs_qqqE",100,0,200,800,0,20,pcz_guess,qqqenergy,"pczguess"); + double pczoffset=30.0; + //plotter->Fill2D("pczguess_vs_pcz_rad="+std::to_string(hitPos.Perp()),100,0,200,150,0,200,pcz_guess,anodeIntersection.Z(),"pczguess"); //entirely qqq-derived position vs entirely PC derived position + plotter->Fill2D("pczguess_vs_pcz_phi="+std::to_string(hitPos.Phi()*180./M_PI),100,0,200,150,0,200,pcz_guess,anodeIntersection.Z()+pczoffset,"pczguess"); //entirely qqq-derived position vs entirely PC derived position + plotter->Fill2D("pczguess_vs_pcz",100,0,200,150,0,200,pcz_guess,anodeIntersection.Z()+pczoffset); + plotter->Fill2D("pcz_vs_pcPhi_rad="+std::to_string(hitPos.Perp()),360,0,360,150,0,200,anodeIntersection.Phi()*180./M_PI,anodeIntersection.Z()+pczoffset,"pczguess"); + } + for (int i = 0; i < sx3.multi; i++) + { + // plotting sx3 strip hits vs anode phi + if (sx3.ch[i] < 8 && anodeIntersection.Perp()>0) + plotter->Fill2D("PCPhi_vs_SX3Strip", 100, -200, 200, 8 * 24, 0, 8 * 24, anodeIntersection.Phi() * 180. / TMath::Pi(), sx3.id[i] * 8 + sx3.ch[i]); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 3) + { + plotter->Fill1D("PC_Z_proj_3C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + } + + plotter->Fill2D("AnodeMaxE_Vs_Cathode_Sum_Energy", 2000, 0, 30000, 2000, 0, 30000, aEMax, cESum, "hGMPC"); + plotter->Fill1D("Correlated_Cathode_MaxAnode", 6, 0, 5, corrcatMax.size(), "hGMPC"); + plotter->Fill2D("Correlated_Cathode_VS_MaxAnodeEnergy", 6, 0, 5, 2000, 0, 30000, corrcatMax.size(), aEMax, "hGMPC"); + plotter->Fill1D("AnodeHits", 12, 0, 11, anodeHits.size(), "hGMPC"); + plotter->Fill2D("AnodeMaxE_vs_AnodeHits", 12, 0, 11, 2000, 0, 30000, anodeHits.size(), aEMax, "hGMPC"); + + if (anodeHits.size() < 1) + { + plotter->Fill1D("NoAnodeHits_CathodeHits", 6, 0, 5, cathodeHits.size(), "hGMPC"); + } + + return kTRUE; +} + +void MakeVertexSX3::Terminate() +{ + plotter->FlushToDisk(); +} diff --git a/anasen_analysis_vignesh/MakeVertexSX3.C.backup b/anasen_analysis_vignesh/MakeVertexSX3.C.backup new file mode 100644 index 0000000..17f0fad --- /dev/null +++ b/anasen_analysis_vignesh/MakeVertexSX3.C.backup @@ -0,0 +1,1114 @@ +#define MakeVertexSX3_cxx + +#include +#include +#include +#include + +#include "MakeVertexSX3.h" +#include "Armory/ClassPW.h" +#include "Armory/HistPlotter.h" +#include "Armory/SX3Geom.h" +#include "gmsx3/intgm_sx3.h" + +#include +#include +#include +#include +#include +#include "TVector3.h" + +#include +#include +#include +#include +#include +#include +#include +#include + +// Global instances +PW pw_contr; +PW pwinstance; +TVector3 hitPos; +double qqqenergy, qqqtimestamp; +intgm_sx3 *matcher=NULL; + + +class Event { +public: + Event(TVector3 p, double e1, double e2, double t1, double t2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2) {} + Event(TVector3 p, double e1, double e2, double t1, double t2, int c1, int c2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2), ch1(c1), ch2(c2) {} + + TVector3 pos; + int ch1=-1; //int(ch1/16) gives qqq id, ch1%16 gives ring# + int ch2=-1; //int(ch2/16) gives qqq id, ch2%16 gives wedge# + double Energy1=-1; //Front for QQQ, Anode for PC + double Energy2=-1; //Back for QQQ, Cathode for PC + double Time1=-1; + double Time2=-1; + +}; + +/*std::vector +Make_QQQClusters(const std::unordered_map& qqqvec) { + std::vector qqqevents; //input events, but combine NN energies + + +}*/ + +// Calibration globals +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +// TCutg *cutQQQ; + +double sx3BackGain[24][4][4] = {{{1.}}}; +double sx3FrontGain[24][4] = {{1.}}; +double sx3FrontOffset[24][4] = {{0.}}; +double sx3RightGain[24][4] = {{1.}}; + +// PC Arrays +double pcSlope[48]; +double pcIntercept[48]; + +HistPlotter *plotter; + +bool HitNonZero; +bool sx3ecut; +bool qqqEcut; + +void MakeVertexSX3::Begin(TTree * /*tree*/) +{ + TString option = GetOption(); + plotter = new HistPlotter("Analyzer_SX3.root", "TFILE"); + matcher = new intgm_sx3(plotter); + pw_contr.ConstructGeo(); + pwinstance.ConstructGeo(); + + // --------------------------------------------------------- + // 1. CRITICAL FIX: Initialize PC Arrays to Default (Raw) + // --------------------------------------------------------- + for (int i = 0; i < 48; i++) + { + pcSlope[i] = 1.0; // Default slope = 1 (preserves Raw energy) + pcIntercept[i] = 0.0; // Default intercept = 0 + } + + // Calculate Crossover Geometry ONCE + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha; + + for (size_t i = 0; i < pwinstance.An.size(); i++) + { + a = pwinstance.An[i].first - pwinstance.An[i].second; + + for (size_t j = 0; j < pwinstance.Ca.size(); j++) + { + c = pwinstance.Ca[j].first - pwinstance.Ca[j].second; + diff = pwinstance.An[i].first - pwinstance.Ca[j].first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + + Crossover[i][j][0].x = pwinstance.An[i].first.X() + alpha * a.X(); + Crossover[i][j][0].y = pwinstance.An[i].first.Y() + alpha * a.Y(); + Crossover[i][j][0].z = pwinstance.An[i].first.Z() + alpha * a.Z(); + + if (Crossover[i][j][0].z < -190 || Crossover[i][j][0].z > 190 || (i+j)%24 == 12) + { + Crossover[i][j][0].z = 9999999; + } + + Crossover[i][j][1].x = alpha; + Crossover[i][j][1].y = 0; + } + } + + // Load PC Calibrations + std::ifstream inputFile("slope_intercept_results.txt"); + if (inputFile.is_open()) + { + std::string line; + int index; + double slope, intercept; + while (std::getline(inputFile, line)) + { + std::stringstream ss(line); + ss >> index >> slope >> intercept; + if (index >= 0 && index <= 47) + { + pcSlope[index] = slope; + pcIntercept[index] = intercept; + } + } + inputFile.close(); + } + else + { + std::cerr << "Error opening slope_intercept.txt" << std::endl; + } + + // Load QQQ Cuts from file + // { + // std::string filename = "QQQ_PCCut.root"; + // TFile *cutFile = TFile::Open(filename.c_str(), "READ"); + // if (cutFile && !cutFile->IsZombie()) + // { + // cutQQQ = (TCutg *)cutFile->Get("cutQQQPC"); + // if (cutQQQ) + // { + // std::cout << "Loaded QQQ PC cut from " << filename << std::endl; + // } + // else + // { + // std::cerr << "Error: cutQQQPC not found in " << filename << std::endl; + // } + // cutFile->Close(); + // } + // } + + // ... (Load QQQ Gains and Calibs - same as before) ... + { + std::string filename = "qqq_GainMatch.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double gainw, gainr; + while (infile >> det >> wedge >> ring >> gainw >> gainr) + { + qqqGain[det][wedge][ring] = gainw; + qqqGainValid[det][wedge][ring] = (gainw > 0); + // std::cout << "QQQ Gain Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " GainW " << gainw << " GainR " << gainr << std::endl; + } + infile.close(); + } + } + { + std::string filename = "qqq_Calib.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double slope; + while (infile >> det >> wedge >> ring >> slope) + { + qqqCalib[det][wedge][ring] = slope; + qqqCalibValid[det][wedge][ring] = (slope > 0); + // std::cout << "QQQ Calib Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " Slope " << slope << std::endl; + } + infile.close(); + } + } + + { + std::ifstream infile("sx3cal/backgains.dat"); + std::string temp; + int backpos, frontpos, clkpos; + std::cout << "foo" << std::endl; + if (infile.is_open()) + while(infile>>clkpos>>temp>>frontpos>>temp>>backpos>>sx3BackGain[clkpos][frontpos][backpos]) + std::cout << sx3BackGain[clkpos][frontpos][backpos] << std::endl; + infile.close(); + + infile.open("sx3cal/frontgains.dat"); + if (infile.is_open()) + while(infile>>clkpos>>temp>>temp>>frontpos>>sx3FrontOffset[clkpos][frontpos]>>sx3FrontGain[clkpos][frontpos]) + std::cout << sx3FrontOffset[clkpos][frontpos] << " " << sx3FrontGain[clkpos][frontpos] << std::endl; + infile.close(); + + infile.open("sx3cal/rightgains.dat"); + if (infile.is_open()) + while(infile>>clkpos>>frontpos>>temp>>sx3RightGain[clkpos][frontpos]) { + sx3RightGain[clkpos][frontpos]=TMath::Abs(sx3RightGain[clkpos][frontpos]); + } + infile.close(); + + } + std::cout << "aaa" << std::endl; +} + +Bool_t MakeVertexSX3::Process(Long64_t entry) +{ + hitPos.Clear(); + qqqenergy = -1; + qqqtimestamp=-1; + HitNonZero = false; + bool qqq1000cut = false; + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + std::vector sx3Events; + if(sx3.multi>1) { + std::array Fsx3; + //std::cout << "-----" << std::endl; + for(int i=0; i=12) continue; + int id = sx3.id[i]; + if(sx3.ch[i]>=8) { + int sx3ch=sx3.ch[i]-8; + sx3ch=(sx3ch+3)%4; + if(sx3ch==0 || sx3ch==3) continue; + float value=sx3.e[i]; + int gch = sx3.id[i]*4+(sx3.ch[i]-8); + Fsx3.at(id).fillevent("BACK",sx3ch,value); + Fsx3.at(id).ts = static_cast(sx3.t[i]); + plotter->Fill2D("sx3backs_raw",100,0,100,800,0,4096,gch,sx3.e[i]); + } else { + int sx3ch=sx3.ch[i]/2; + double value=sx3.e[i]; + if(sx3.ch[i]%2==0) { + Fsx3.at(id).fillevent("FRONT_L",sx3ch,value*sx3RightGain[id][sx3ch]); + } else { + Fsx3.at(id).fillevent("FRONT_R",sx3ch,value); + } + } + } + for(int id=0; id<12; id++) { + Fsx3.at(id).validate(); + auto det = Fsx3.at(id); + bool no_charge_sharing_strict = det.valid_front_chans.size()==1 && det.valid_back_chans.size()==1; + if(det.valid) { + //std::cout << det.frontEL << " " << det.frontEL*sx3RightGain[id][det.stripF] << std::endl; + plotter->Fill2D("be_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF)+"_b"+std::to_string(det.stripB),200,-1,1,800,0,8192, + det.frontX,det.backE,"evsx"); + //std::cout << sx3BackGain[id][det.stripF][det.stripB] << " " << sx3FrontGain[id][det.stripF] << std::endl; + plotter->Fill2D("matched_be_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF),200,-30,30,800,0,8192, + det.frontX*sx3FrontGain[id][det.stripF]+sx3FrontOffset[id][det.stripF],det.backE*sx3BackGain[id][det.stripF][det.stripB],"evsx_matched"); + //plotter->Fill2D("fe_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF)+"_"+std::to_string(det.stripB),200,-1,1,800,0,4096,det.frontX,det.backE,"evsx"); + plotter->Fill2D("l_vs_r_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF),800,0,4096,800,0,4096,det.frontEL,det.frontER,"l_vs_r"); + } + if(det.valid && (id ==9 || id==7 || id == 1 || id==3) && det.stripF!=DEFAULT_NULL && det.stripB!=DEFAULT_NULL) { + double z = det.frontX*sx3FrontGain[id][det.stripF]+sx3FrontOffset[id][det.stripF]; + double backE = det.backE*sx3BackGain[id][det.stripF][det.stripB]; + Event sx3ev(TVector3(0,0,z),backE,-1,det.ts,-1,det.stripB+4*id,det.stripF+4*id); + sx3Events.push_back(sx3ev); + } + } + } + //return kTRUE; + // QQQ Processing + + int qqqCount = 0; + int qqqAdjCh = 0; + // REMOVE WHEN RERUNNING USING THE NEW CALIBRATION FILE + for (int i = 0; i < qqq.multi; i++) + { + //if ((qqq.id[i] == 3 || qqq.id[i] == 1) && qqq.ch[i] < 16) + if (qqq.id[i] == 1 && qqq.ch[i] < 16) //for run 12, 26Al + { + qqq.ch[i] = 16 - qqq.ch[i]; + } + } + for (int i = 0; i < qqq.multi; i++) + { + if (qqq.id[i] == 0 && qqq.ch[i] >= 16) + { + qqq.ch[i] = 31 - qqq.ch[i] + 16; + } + } + + std::vector QQQ_Events, PC_Events; + std::vector QQQ_Events_Raw, PC_Events_Raw; + std::vector QQQ_Events2; //clustering done + + std::unordered_map> qvecr[4], qvecw[4]; + if(qqq.multi>1) { + if(qqq.multi>=3) std::cout << "-----" << std::endl; + for(int i=0; i=3) std::cout << std::setprecision(16) << "qqq"<< qqq.id[i] << " " << std::string(qqq.ch[i]/16?"ring":"wedge") << qqq.ch[i]%16 << " " << qqq.e[i] << " " << qqq.t[i] - qqq.t[0] << std::endl; + if(qqq.ch[i]/16) { + if(qvecr[qqq.id[i]].find(qqq.ch[i])!=qvecr[qqq.id[i]].end()) std::cout << "mayday!" << std::endl; + qvecr[qqq.id[i]][qqq.ch[i]] = std::tuple(qqq.id[i],qqq.ch[i],qqq.e[i],qqq.t[i]); + } else { + if(qvecw[qqq.id[i]].find(qqq.ch[i])!=qvecw[qqq.id[i]].end()) std::cout << "mayday!" << std::endl; + qvecw[qqq.id[i]][qqq.ch[i]] = std::tuple(qqq.id[i],qqq.ch[i],qqq.e[i],qqq.t[i]); + } + } + } + + +/* std::tuple maxRevent, maxWevent; + for(int qqqid=0; qqqid<4; qqqid) { + for(int i=0; i<16; i++) { + if(qvecr[qqqid].find(i)==qvecr[qqqid].end()) + ;//do nothing + else if(std::get<2>(qvecr[qqqid][i])>std::get<2>(maxRevent)) { + maxRevent = qvecr[qqqid][i]; + } + if(qvecw[qqqid].find(i)==qvecw[qqqid].end()) + ;//do nothing + else if(std::get<2>(qvecw[qqqid][i])>std::get<2>(maxWevent)) { + maxWevent = qvecw[qqqid][i]; + } + } + if(qvecr) + } + + int qcount=0; + while(qcount< 16) { + if(qvecr[qqqid].find(qcount)==qvecr[qqqid].end()) { + qcount++; + continue; + } + qrCluster.clear(); + std::tuple maxE_Event; + int ctr2=qcount; + do { + qrCluster.emplace_back(qvecr[qqqid][ctr2]); + if(std::get<2>(qvecr[qqqid][ctr2])>maxE) { + maxE_Event = qvecr[qqqid][ctr2]; + } + ctr2+=1; + } while(qvecr[qqqid].find(ctr2)!=qvecr[qqqid].end()); + + if(qvecr[qqqid].find(maxch-1)!=qvecr[qqqid].end()) { + std::get<2>(maxE_Event) += std::get<2>(qvecr[qqqid][maxch-1]); + } else if(qvecr[qqqid].find(maxch+1)!=qvecr[qqqid].end()) { + std::get<2>(maxE_Event) += std::get<2>(qvecr[qqqid][maxch+1]); + } + + qrClusters.push_back(std::move(qrCluster)); + qcount = ctr2; //we already dealt with segments until the last value of ctr2 + } + + int ch = 0; + while(ch < 16) { + if(qvecr[qqqid].find(ch)==qvecr[qqqid].end()) { + ch++; + continue; + } else { + if(qvecr[qqqid].find(ch+1)==qvecr[qqqid].end()) { + } + } + ch+=1; + } + + qcount=0; + while(qcount< 16) { + if(qvecw[qqqid].find(v)==qvecw[qqqid].end()) { + qcount++; + continue; + } + qwCluster.clear(); + int ctr2=qcount; + do { + qwCluster.emplace_back(qvecw[qqqid][ctr2]); + ctr2+=1; + } while(qvecw[qqqid].find(ctr2)!=qvecw[qqqid].end()); + qwClusters.push_back(std::move(qwCluster)); + qcount = ctr2; //we already dealt with segments until the last value of ctr2 + } + + + for(auto qrs: qrClusters) { + for(auto qr: qrs) { + + } + } + }*/ + + bool PCQQQTimeCut = false; + for (int i = 0; i < qqq.multi; i++) { + plotter->Fill2D("QQQ_Index_Vs_Energy", 16 * 8, 0, 16 * 8, 2000, 0, 16000, qqq.index[i], qqq.e[i], "hRawQQQ"); + + for (int j = 0; j < qqq.multi; j++) { + if (j == i) + continue; + plotter->Fill2D("QQQ_Coincidence_Matrix", 16 * 8, 0, 16 * 8, 16 * 8, 0, 16 * 8, qqq.index[i], qqq.index[j], "hRawQQQ"); + } + + for (int k = 0; k < pc.multi; k++) { + if (pc.index[k] < 24 && pc.e[k] > 50) { + plotter->Fill2D("QQQ_Vs_Anode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + plotter->Fill2D("QQQ_Vs_PC_Index", 16 * 8, 0, 16 * 8, 24, 0, 24, qqq.index[i], pc.index[k], "hRawQQQ"); + } + else if (pc.index[k] >= 24 && pc.e[k] > 50) { + plotter->Fill2D("QQQ_Vs_Cathode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + } + } + + for (int j = i + 1; j < qqq.multi; j++) { + if (qqq.id[i] == qqq.id[j]) { + qqqCount++; + + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + double tWedge = 0.0; + + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + tWedge = static_cast(qqq.t[i]); + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i]; + tRing = static_cast(qqq.t[i]); + tWedge = static_cast(qqq.t[j]); + } + else + continue; + + plotter->Fill1D("Wedgetime_Vs_Ringtime", 100, -1000, 1000, tWedge - tRing, "hTiming"); + plotter->Fill2D("RingE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chRing + qqq.id[i] * 16, eRing, "hRawQQQ"); + plotter->Fill2D("WedgeE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chWedge + qqq.id[i] * 16, eWedge, "hRawQQQ"); + + if (qqqCalibValid[qqq.id[i]][chWedge][chRing]) { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + + if(eRingMeV/eWedgeMeV > 3.0 || eRingMeV/eWedgeMeV<1.0/3.0) continue; + //if(eRingMeV<4.0 || eWedgeMeV<4.0) continue; + + double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?" + + Event qqqevent(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),23+75+30), eRingMeV, eWedgeMeV, tRing, tWedge,chRing+qqq.id[i]*16, chWedge+qqq.id[i]*16); + Event qqqeventr(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),23+75+30), eRing, eWedge, tRing, tWedge,chRing+qqq.id[i]*16, chWedge+qqq.id[i]*16); + QQQ_Events.push_back(qqqevent); + QQQ_Events_Raw.push_back(qqqeventr); + plotter->Fill2D("QQQCartesianPlot", 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + plotter->Fill2D("QQQCartesianPlot" + std::to_string(qqq.id[i]), 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + if (PCQQQTimeCut) { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ"); + } + else + continue; + + plotter->Fill2D("WedgeE_Vs_RingECal", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ"); + plotter->Fill2D("WedgeE_Vs_RingECal_selected", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ"); + + for (int k = 0; k < pc.multi; k++) + { + plotter->Fill2D("RingCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index" + std::to_string(qqq.id[i]), 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k]); + plotter->Fill2D("RingCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + + if (pc.index[k] < 24 && pc.e[k] > 50) + { + plotter->Fill2D("Timing_Difference_QQQ_PC", 500, -2000, 2000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + plotter->Fill2D("DelT_Vs_QQQRingECal", 500, -2000, 2000, 1000, 0, 10, tRing - static_cast(pc.t[k]), eRingMeV, "hTiming"); + plotter->Fill2D("CalibratedQQQEvsPCE_R", 1000, 0, 10, 2000, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("CalibratedQQQEvsPCE_W", 1000, 0, 10, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ"); + if (tRing - static_cast(pc.t[k]) < -150) // proton tests, 27Al + //if (tRing - static_cast(pc.t[k]) < -150 && tRing - static_cast(pc.t[k]) > -450) // 27Al + //if (tRing - static_cast(pc.t[k]) < -70 && tRing - static_cast(pc.t[k]) > -150) // 17F + { + PCQQQTimeCut = true; + } + } + + if (pc.index[k] >= 24 && pc.e[k] > 50) { + plotter->Fill2D("Timing_Difference_QQQ_PC_Cathode", 500, -2000, 2000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + } + } //end of pc k loop + + if (!HitNonZero) { + double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?" + double x = rho * TMath::Cos(theta); + double y = rho * TMath::Sin(theta); + hitPos.SetXYZ(x, y, (23 + 75 + 30)); + qqqenergy = eRingMeV; + qqqtimestamp = tRing; + HitNonZero = true; + } + } // if j==i + } //j loop end + } //i loop end + + plotter->Fill1D("QQQ_Multiplicity", 10, 0, 10, qqqCount, "hRawQQQ"); + + /*if(QQQ_Events.size()>=1) { + std::cout<< " ---->" << std::endl; + for(auto qe: QQQ_Events) { + std::cout << qe.ch1/16 << " " <> WireEvent; //this stores nearest neighbour wire events, or a 'cluster' + WireEvent aWireEvents, cWireEvents; //naming for book keeping + aWireEvents.clear(); + aWireEvents.reserve(24); + + // PC Gain Matching and Filling + double anodeT = -99999; + double cathodeT = 99999; + int anodeIndex = -1; + int cathodeIndex = -1; + for (int i = 0; i < pc.multi; i++) + { + if (pc.e[i] > 50) + { + plotter->Fill2D("PC_Index_Vs_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], static_cast(pc.e[i]), "hRawPC"); + } else { + continue; + } + + if (pc.index[i] < 48) + { + pc.e[i] = pcSlope[pc.index[i]] * pc.e[i] + pcIntercept[pc.index[i]]; + plotter->Fill2D("PC_Index_VS_GainMatched_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], pc.e[i], "hGMPC"); + } + + if (pc.index[i] < 24) + { + anodeT = static_cast(pc.t[i]); + anodeIndex = pc.index[i]; + aWireEvents[pc.index[i]] = std::tuple(pc.index[i],pc.e[i],static_cast(pc.t[i])); + } + else + { + cathodeT = static_cast(pc.t[i]); + cathodeIndex = pc.index[i] - 24; + cWireEvents[pc.index[i]-24] = std::tuple(pc.index[i]-24,pc.e[i],static_cast(pc.t[i])); + } + + if (anodeT != -99999 && cathodeT != 99999) + { + for (int j = 0; j < qqq.multi; j++) + { + plotter->Fill1D("PC_Time_qqq", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + plotter->Fill2D("PC_Time_Vs_QQQ_ch", 200, -2000, 2000, 16 * 8, 0, 16 * 8, anodeT - cathodeT, qqq.ch[j], "hTiming"); + plotter->Fill2D("PC_Time_vs_AIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, anodeIndex, "hTiming"); + plotter->Fill2D("PC_Time_vs_CIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, cathodeIndex, "hTiming"); + // plotter->Fill1D("PC_Time_A" + std::to_string(anodeIndex) + "_C" + std::to_string(cathodeIndex), 200, -1000, 1000, anodeT - cathodeT, "TimingPC"); + } + + for (int j = 0; j < sx3.multi; j++) + { + plotter->Fill1D("PC_Time_sx3", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + + plotter->Fill1D("PC_Time", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + + for (int j = i + 1; j < pc.multi; j++) + { + plotter->Fill2D("PC_Coincidence_Matrix", 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("PC_Coincidence_Matrix_anodeMinusCathode_lt_-200_" + std::to_string(anodeT - cathodeT < -200), 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("Anode_V_Anode", 24, 0, 24, 24, 0, 24, pc.index[i], pc.index[j], "hGMPC"); + } + } + + anodeHits.clear(); + cathodeHits.clear(); + corrcatMax.clear(); + + int aID = 0; + int cID = 0; + double aE = 0; + double cE = 0; + double aESum = 0; + double cESum = 0; + double aEMax = 0; + int aIDMax = 0; + + + + for (int i = 0; i < pc.multi; i++) { + // if (pc.e[i] > 100) + { + if (pc.index[i] < 24) { + anodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + } + else if (pc.index[i] >= 24) { + cathodeHits.push_back(std::pair(pc.index[i] - 24, pc.e[i])); + } + } + } + + std::sort(anodeHits.begin(),anodeHits.end(),[](std::pair a, std::pair b){ return a.first < b.first;}); + std::sort(cathodeHits.begin(),cathodeHits.end(),[](std::pair a, std::pair b){ return a.first < b.first;}); + + //clusters = collection of (collection of wires) where each wire is (index, energy, timestamp) + std::vector>> aClusters = pwinstance.Make_Clusters(aWireEvents); + std::vector>> cClusters = pwinstance.Make_Clusters(cWireEvents); + + std::vector> sumE_AC; + for(auto aCluster: aClusters) { + for(auto cCluster: cClusters) { + if(aCluster.size()<=1 && cCluster.size()<=1) continue; + auto [crossover,alpha,apSumE,cpSumE,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE] = pwinstance.FindCrossoverProperties(aCluster, cCluster); + if(alpha!=9999999 && apSumE!=-1) { + //Event PCEvent(crossover,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE); + //Event PCEvent(crossover,apSumE,cpSumE,apTSMaxE,cpTSMaxE); + Event PCEvent(crossover,apSumE,cpMaxE,apTSMaxE,cpTSMaxE); //run12 shows cathode-max and anode-sum provide best dE signals. + //std::cout << apSumE << " " << crossover.Perp() << " " << apMaxE << " " << apTSMaxE << std::endl; + PC_Events.push_back(PCEvent); + sumE_AC.push_back(std::pair(apSumE,cpSumE)); + } + } + } + if(QQQ_Events.size() && PC_Events.size()) + plotter->Fill2D("PCEv_vs_QQQEv",20,0,20,20,0,20,QQQ_Events.size(),PC_Events.size()); + + for(auto pcevent:PC_Events) { + for(auto sx3event:sx3Events) { + plotter->Fill1D("dt_pcA_sx3B"+std::to_string(sx3event.ch2),640,-2000,2000,sx3event.Time1 - pcevent.Time1); + plotter->Fill1D("dt_pcC_sx3B"+std::to_string(sx3event.ch2),640,-2000,2000,sx3event.Time1 - pcevent.Time2); + plotter->Fill2D("dE_E_Anodesx3B",400,0,10,800,0,40000,sx3event.Energy1*0.001,pcevent.Energy1); + + plotter->Fill2D("dE_E_Cathodesx3B",400,0,10,800,0,10000,sx3event.Energy1*0.001,pcevent.Energy2); + double sx3z = sx3event.pos.Z()+(75.0/2.0)+23.0-90.0; //w.r.t target origin at 90 for run12 + double sx3rho = 88.0; + double sx3theta = TMath::ATan2(sx3rho,sx3z); + double pczguess = 40.0/TMath::Tan(sx3theta) + 90.0; + plotter->Fill2D("pcz_vs_sx3z",300,0,200,150,0,200,pczguess,pcevent.pos.Z()+25.); + plotter->Fill2D("pcz_vs_sx3z"+std::to_string(sx3event.ch2),300,0,200,150,0,200,pczguess,pcevent.pos.Z()+25); + } + } + + for(auto pcevent: PC_Events) { + for(auto qqqevent: QQQ_Events) { + plotter->Fill1D("dt_pcA_qqqR",640,-2000,2000,qqqevent.Time1 - pcevent.Time1); + plotter->Fill1D("dt_pcC_qqqW",640,-2000,2000,qqqevent.Time2 - pcevent.Time2); + plotter->Fill2D("dE_E_AnodeQQQR",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1); + plotter->Fill2D("dE_E_CathodeQQQR",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2); + double sinTheta = TMath::Sin((qqqevent.pos - TVector3(0,0,90)).Theta())/TMath::Sin((TVector3(51.5,0,128.) - TVector3(0,0,90)).Theta()); + plotter->Fill2D("dE2_E_AnodeQQQR",400,0,10,800,0,40000,qqqevent.Energy1,pcevent.Energy1*sinTheta); + plotter->Fill2D("dE2_E_CathodeQQQR",400,0,10,800,0,10000,qqqevent.Energy2,pcevent.Energy2*sinTheta); + + if(qqqevent.pos.Phi() <= pcevent.pos.Phi()+TMath::Pi()/4. && qqqevent.pos.Phi() >= pcevent.pos.Phi()-TMath::Pi()/4.) { + plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut"); + double pcz_guess = 40.0/TMath::Tan((qqqevent.pos-TVector3(0,0,90)).Theta()) + 90; //this is ideally kept to be all QQQ+userinput for calibration of pcz + plotter->Fill2D("pczguess_vs_pc",300,0,200,150,0,200,pcz_guess,pcevent.pos.Z()+25.,"phicut"); + plotter->Fill2D("pczguess_vs_pc_phi="+std::to_string(qqqevent.pos.Phi()*180./M_PI),300,0,200,150,0,200,pcz_guess,pcevent.pos.Z()+25.,"phicut"); + //plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut"); + } + } + } + //HALFTIME! Can stop here in future versions + //return kTRUE; + + if (anodeHits.size() >= 1 && cathodeHits.size() >= 1) + { + // 2. CRITICAL FIX: Define reference vector 'a' + // In Analyzer.cxx, 'a' was left over from the loop. We use the first anode wire as reference here. + // (Assuming pwinstance.An is populated and wires are generally parallel). + TVector3 refAnode = pwinstance.An[0].first - pwinstance.An[0].second; + + { + for (const auto &anode : anodeHits) + { + aID = anode.first; + aE = anode.second; + aESum += aE; + if (aE > aEMax) + { + aEMax = aE; + aIDMax = aID; + } + } + + for (const auto &cathode : cathodeHits) + { + cID = cathode.first; + cE = cathode.second; + plotter->Fill2D("AnodeMax_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aIDMax, cID, "hRawPC"); + plotter->Fill2D("Anode_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aID, cID, "hRawPC"); + plotter->Fill2D("Anode_vs_CathodeE", 2000, 0, 30000, 2000, 0, 30000, aE, cE, "hGMPC"); + plotter->Fill2D("CathodeMult_V_CathodeE", 6, 0, 6, 2000, 0, 30000, cathodeHits.size(), cE, "hGMPC"); + for (int j = -4; j < 3; j++) + { + if ((aIDMax + 24 + j) % 24 == 23 - cID) + { + corrcatMax.push_back(std::pair(cID, cE)); + cESum += cE; + } + } + } + } + } + + TVector3 anodeIntersection,vector_closest_to_z; + anodeIntersection.Clear(); + vector_closest_to_z.Clear(); + if (corrcatMax.size() > 0) + { + double x = 0, y = 0, z = 0; + for (const auto &corr : corrcatMax) + { + if (Crossover[aIDMax][corr.first][0].z > 9000000) + continue; + if (cESum > 0) + { + x += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].x; + y += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].y; + z += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].z; + } + } + if (x == 0 && y == 0 && z == 0) + ; + // to ignore events with no valid crossover points + else + anodeIntersection = TVector3(x, y, z); + // << "Anode Intersection: " << anodeIntersection.X() << ", " << anodeIntersection.Y() << ", " << anodeIntersection.Z() << std::endl; + } + bool PCQQQPhiCut = false; + // flip the algorithm for cathode 1 multi anode events + if ((hitPos.Phi() > (anodeIntersection.Phi() - TMath::PiOver4())) && (hitPos.Phi() < (anodeIntersection.Phi() + TMath::PiOver4()))) { + PCQQQPhiCut = true; + } + + for (double Tz = 60; Tz <= 100; Tz += 1.0) + { + TVector3 TargetPos(0, 0, Tz); + if(PCQQQPhiCut && anodeIntersection.Perp()>0 && anodeIntersection.Z()!=0 && cathodeHits.size()>=2) { + plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut) + "_TZ" + std::to_string(Tz), 400, 0, 180, 90, 0, 90, (anodeIntersection - TargetPos).Theta() * 180. / TMath::Pi(), (hitPos - TargetPos).Theta() * 180. / TMath::Pi(), "TPosVariation"); + //plotter->Fill2D("R_ratio_to_Z_ratio" + std::to_string(PCQQQTimeCut) + "_TZ" + std::to_string(Tz), 100, -2, 2, 100, -2, 2, (anodeIntersection - TargetPos).Z()/(hitPos-TargetPos).Z(), ((anodeIntersection - TargetPos).Perp()+2.5)/(hitPos-TargetPos).Perp(), "TPosVariation"); + } + } + + if (anodeIntersection.Z() != 0 && anodeIntersection.Perp()>0 && HitNonZero) + { + plotter->Fill1D("PC_Z_Projection", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("Z_Proj_VsDelTime", 600, -300, 300, 200, -2000, 2000, anodeIntersection.Z(), anodeT - cathodeT, "hPCzQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi", 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + //plotter->Fill2D("Inttheta_vs_QQQtheta", 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + //plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut)+ "_PC"+std::to_string(PCQQQPhiCut), 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() >= 2) + plotter->Fill1D("PC_Z_Projection_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 1) + { + plotter->Fill1D("PC_Z_proj_1C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_1C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill1D("PC_Z_proj_2C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_2C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() > 2) + { + plotter->Fill1D("PC_Z_proj_nC", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_nC", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + plotter->Fill2D("AHits_vs_CHits", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // make another plot with nearest neighbour constraint + bool hasNeighbourAnodes = false; + bool hasNeighbourCathodes = false; + + // 1. Check Anodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < anodeHits.size(); i++) + { + for (size_t j = i + 1; j < anodeHits.size(); j++) + { + int diff = std::abs(anodeHits[i].first - anodeHits[j].first); + if (diff == 1 || diff == 23) + { // 23 handles the cylindrical wrap + hasNeighbourAnodes = true; + break; + } + } + if (hasNeighbourAnodes) + break; + } + + // 2. Check Cathodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < cathodeHits.size(); i++) + { + for (size_t j = i + 1; j < cathodeHits.size(); j++) + { + int diff = std::abs(cathodeHits[i].first - cathodeHits[j].first); + if (diff == 1 || diff == 23) + { + hasNeighbourCathodes = true; + break; + } + } + if (hasNeighbourCathodes) + break; + } + + // --------------------------------------------------------- + // FILL PLOTS + // --------------------------------------------------------- + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + { + plotter->Fill2D("AHits_vs_CHits_NA" + std::to_string(hasNeighbourAnodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + plotter->Fill2D("AHits_vs_CHits_NC" + std::to_string(hasNeighbourCathodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // Constraint Plot: Only fill if BOTH planes have adjacent hits + // This effectively removes events with only isolated single-wire hits (noise) + if (hasNeighbourAnodes && hasNeighbourCathodes) + { + plotter->Fill2D("AHits_vs_CHits_NN", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + } + } + + if (HitNonZero && anodeIntersection.Z() != 0) + { + pw_contr.CalTrack2(hitPos, anodeIntersection); + plotter->Fill1D("VertexRecon", 600, -1300, 1300, pw_contr.GetZ0()); + plotter->Fill1D("VertexRecon_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, pw_contr.GetZ0()); + + if (cathodeHits.size() == 2) + plotter->Fill1D("VertexRecon_2c_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, pw_contr.GetZ0()); + + TVector3 x2(anodeIntersection), x1(hitPos); + + TVector3 v = x2-x1; + double t_minimum = -1.0*(x1.X()*v.X()+x1.Y()*v.Y())/(v.X()*v.X()+v.Y()*v.Y()); + vector_closest_to_z = x1 + t_minimum*v; + + plotter->Fill1D("VertexRecon_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + if(vector_closest_to_z.Perp() < 20) { + plotter->Fill1D("VertexRecon_RadialCut_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + } + + plotter->Fill2D("VertexRecon_XY_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 100,-100,100, vector_closest_to_z.X(), vector_closest_to_z.Y() ,"customVertex"); + if(cathodeHits.size()==2) { + plotter->Fill1D("VertexRecon2C_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + if(vector_closest_to_z.Perp() < 20) { + plotter->Fill1D("VertexRecon2C_RadialCut_Z_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z() ,"customVertex"); + } + plotter->Fill2D("VertexRecon2C_XY_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 100,-100,100, vector_closest_to_z.X(), vector_closest_to_z.Y() ,"customVertex"); + plotter->Fill2D("VertexRecon2C_RhoZ_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 100, -100, 100, 600,-1300,1300, vector_closest_to_z.Perp(), vector_closest_to_z.Z() ,"customVertex"); + plotter->Fill2D("VertexRecon2C_Z_vs_QQQE_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -1300, 1300, 800,0,20000, vector_closest_to_z.Z(), qqqenergy ,"customVertex"); + } + + } + + for (int i = 0; i < qqq.multi; i++) + { + if(anodeIntersection.Perp() > 0) { //suppress x,y=0,0 events + if (PCQQQTimeCut) { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + } + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + int qqqID = -1; + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + qqqID = qqq.id[i]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + tRing = static_cast(qqq.t[i]); + eRing = qqq.e[i]; + qqqID = qqq.id[i]; + } + else + continue; + + if (qqqCalibValid[qqq.id[i]][chRing][chWedge]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + } + else + continue; + + // if (anodeIntersection.Z() != 0) + { + plotter->Fill2D("PC_Z_vs_QQQRing", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill2D("PC_Z_vs_QQQRing_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQRing_2C" + std::to_string(qqq.id[i]), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQWedge_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chWedge, "hPCzQQQ"); + } + plotter->Fill2D("VertexRecon_QQQRingTC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, 16, 0, 16, vector_closest_to_z.Z(), chRing, "hPCQQQ"); + double phi = TMath::ATan2(anodeIntersection.Y(), anodeIntersection.X()) * 180. / TMath::Pi(); + plotter->Fill2D("PolarAngle_Vs_QQQWedge" + std::to_string(qqqID), 360, -360, 360, 16, 0, 16, phi, chWedge, "hPCQQQ"); + // plotter->Fill2D("EdE_PC_vs_QQQ_timegate_ls1000"+std::to_string()) + + plotter->Fill2D("PC_Z_vs_QQQRing_Det" + std::to_string(qqqID), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCQQQ"); + //double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + //double rho = 50. + 40. / 16. * (chRing + 0.5); + + for (int k = 0; k < pc.multi; k++) + { + if(pc.index[k] >= 24) + continue; + +// double sinTheta = TMath::Sin((hitPos-vector_closest_to_z).Theta()); + double sinTheta = TMath::Sin((anodeIntersection-TVector3(0,0,90.0)).Theta()); +// double sinTheta = TMath::Sin((anodeIntersection-vector_closest_to_z).Theta()); +// double sinTheta = TMath::Sin((hitPos-TVector3(0,0,30.0)).Theta()); +// double sinTheta = TMath::Sin(hitPos.Theta()); + + if(cathodeHits.size()==2 && PCQQQPhiCut) { + plotter->Fill2D("CalibratedQQQE_RvsCPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsCPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_RvsPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsPCE_TC" + std::to_string(PCQQQTimeCut) , 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("PCQQQ_dTimevsdPhi", 200, -2000, 2000, 80, -200, 200, tRing - static_cast(pc.t[k]), (hitPos.Phi()-anodeIntersection.Phi()) * 180. / TMath::Pi(), "hTiming"); + } + + } + }///qqq i==j case end + } //j loop end + } // qqq i loop end + + TVector3 guessVertex(0,0,90.); //for run12, subtract anodeIntersection.Z() by ~74.0 seems to work + //rho=40.0 mm is halfway between the cathodes(rho=42) and anodes(rho=37) + double pcz_guess = 42.0/TMath::Tan((hitPos-guessVertex).Theta()) + guessVertex.Z(); //this is ideally kept to be all QQQ+userinput for calibration of pcz + if(PCQQQTimeCut && PCQQQPhiCut && hitPos.Perp()>0 && anodeIntersection.Perp()>0 && cathodeHits.size()>=2) { + plotter->Fill2D("pczguess_vs_qqqE",100,0,200,800,0,20,pcz_guess,qqqenergy,"pczguess"); + double pczoffset=30.0; + //plotter->Fill2D("pczguess_vs_pcz_rad="+std::to_string(hitPos.Perp()),100,0,200,150,0,200,pcz_guess,anodeIntersection.Z(),"pczguess"); //entirely qqq-derived position vs entirely PC derived position + plotter->Fill2D("pczguess_vs_pcz_phi="+std::to_string(hitPos.Phi()*180./M_PI),100,0,200,150,0,200,pcz_guess,anodeIntersection.Z()+pczoffset,"pczguess"); //entirely qqq-derived position vs entirely PC derived position + plotter->Fill2D("pczguess_vs_pcz",100,0,200,150,0,200,pcz_guess,anodeIntersection.Z()+pczoffset); + plotter->Fill2D("pcz_vs_pcPhi_rad="+std::to_string(hitPos.Perp()),360,0,360,150,0,200,anodeIntersection.Phi()*180./M_PI,anodeIntersection.Z()+pczoffset,"pczguess"); + } + for (int i = 0; i < sx3.multi; i++) + { + // plotting sx3 strip hits vs anode phi + if (sx3.ch[i] < 8 && anodeIntersection.Perp()>0) + plotter->Fill2D("PCPhi_vs_SX3Strip", 100, -200, 200, 8 * 24, 0, 8 * 24, anodeIntersection.Phi() * 180. / TMath::Pi(), sx3.id[i] * 8 + sx3.ch[i]); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 3) + { + plotter->Fill1D("PC_Z_proj_3C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + } + + plotter->Fill2D("AnodeMaxE_Vs_Cathode_Sum_Energy", 2000, 0, 30000, 2000, 0, 30000, aEMax, cESum, "hGMPC"); + plotter->Fill1D("Correlated_Cathode_MaxAnode", 6, 0, 5, corrcatMax.size(), "hGMPC"); + plotter->Fill2D("Correlated_Cathode_VS_MaxAnodeEnergy", 6, 0, 5, 2000, 0, 30000, corrcatMax.size(), aEMax, "hGMPC"); + plotter->Fill1D("AnodeHits", 12, 0, 11, anodeHits.size(), "hGMPC"); + plotter->Fill2D("AnodeMaxE_vs_AnodeHits", 12, 0, 11, 2000, 0, 30000, anodeHits.size(), aEMax, "hGMPC"); + + if (anodeHits.size() < 1) + { + plotter->Fill1D("NoAnodeHits_CathodeHits", 6, 0, 5, cathodeHits.size(), "hGMPC"); + } + + return kTRUE; +} + +void MakeVertexSX3::Terminate() +{ + /* + // -------------------------------------------------------- + // Section 2 : Gainmatcher minimizer code begins now + std::string minName = "Minuit2"; + std::string algoName = "migrad"; + double defval = 1.0; + + ROOT::Math::Minimizer* minimum = ROOT::Math::Factory::CreateMinimizer(minName, algoName); + if (!minimum) { + std::cerr << "Error: cannot create minimizer \"" << minName + << "\". Maybe the required library was not built?" << std::endl; + return; + } + + // set tolerance , etc... + minimum->SetMaxFunctionCalls(1000000000); // for Minuit/Minuit2 + minimum->SetMaxIterations(10000000); // for GSL + minimum->SetTolerance(0.1); + minimum->SetPrintLevel(1); + + ROOT::Math::Functor f(matcher,&intgm_sx3::eval,24); + matcher->print(); + minimum->SetFunction(f); + + std::vector inparams; + for(int i=0; i<24; i++) { + if(i<16) { + minimum->SetVariable(i,Form("bg%d_%d",i/4,i%4),4.0,0.1); + inparams.emplace_back(4.0); + } else if(i<20) { + minimum->SetVariable(i,Form("r%d",i-20),1.0,0.1); + inparams.emplace_back(1.0); + } else if(i<24) { + minimum->SetVariable(i,Form("stretch%d",i-24),1.0,0.1); + inparams.emplace_back(1.0); + } + minimum->SetVariableLowerLimit(i, 0.0); + } + //minimum->SetFixedVariable(2,"bg2",defval); + + std::ofstream ofile("scratch/results.txt"); + auto oldbuf = std::cerr.rdbuf(); + std::cerr.rdbuf(ofile.rdbuf()); + matcher->plot("before",inparams.data()); + minimum->Minimize(); // do the minimization + + const double *xs = minimum->X(); + std::vector outparams(xs, xs+24); + //outparams[2] = defval; + matcher->plot("after",outparams.data()); + + std::cerr << "#Minval:" << minimum->MinValue() << " status: " << minimum->Status() << std::endl; + for(int i=0; i<24; i++) { + std::cerr << Form("p%02d %g\n",i,outparams.at(i)); + } + + std::cerr.rdbuf(oldbuf); + ofile.close(); + */ + plotter->FlushToDisk(); + delete matcher; +} diff --git a/anasen_analysis_vignesh/MakeVertexSX3.h b/anasen_analysis_vignesh/MakeVertexSX3.h new file mode 100644 index 0000000..ed02cb7 --- /dev/null +++ b/anasen_analysis_vignesh/MakeVertexSX3.h @@ -0,0 +1,132 @@ +#ifndef MakeVertexSX3_h +#define MakeVertexSX3_h + +#include +#include +#include +#include +#include +#include +#include // Required for vectors +#include // Required for std::pair + +#include "Armory/ClassDet.h" +#include "Armory/ClassPW.h" // YOU ADDED THIS (Correct! Defines Coord) + +class MakeVertexSX3 : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + Det misc; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + TBranch *b_miscMulti; //! + TBranch *b_miscID; //! + TBranch *b_miscCh; //! + TBranch *b_miscE; //! + TBranch *b_miscT; //! + TBranch *b_miscTf; //! + + // 1. Geometry Cache + Coord Crossover[24][24][2]; + + // 2. Persistent Vectors (REQUIRED for the optimized .cxx to work) + std::vector> anodeHits; + std::vector> cathodeHits; + std::vector> corrcatMax; + std::vector> corranoMax; + std::vector cathodeTimes; + std::vector anodeTimes; + + MakeVertexSX3(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~MakeVertexSX3() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(MakeVertexSX3,0); +}; + +#endif + +#ifdef MakeVertexSX3_cxx +void MakeVertexSX3::Init(TTree *tree){ + + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + fChain->SetBranchAddress("miscMulti", &misc.multi, &b_miscMulti); + fChain->SetBranchAddress("miscID", &misc.id, &b_miscID); + fChain->SetBranchAddress("miscCh", &misc.ch, &b_miscCh); + fChain->SetBranchAddress("miscE", &misc.e, &b_miscE); + fChain->SetBranchAddress("miscT", &misc.t, &b_miscT); +} + +Bool_t MakeVertexSX3::Notify(){ + return kTRUE; +} + +void MakeVertexSX3::SlaveBegin(TTree * /*tree*/){ + // TString option = GetOption(); +} + +void MakeVertexSX3::SlaveTerminate(){ +} +#endif // #ifdef MakeVertexSX3_cxx diff --git a/anasen_analysis_vignesh/MatchAndPlotCentroids.C b/anasen_analysis_vignesh/MatchAndPlotCentroids.C new file mode 100644 index 0000000..333675d --- /dev/null +++ b/anasen_analysis_vignesh/MatchAndPlotCentroids.C @@ -0,0 +1,133 @@ +#include +#include +#include +#include +#include +#include +#include +#include +#include + + + +void MatchAndPlotCentroids() { + // Open the centroid data file + std::ifstream inputFile("centroids.txt"); + if (!inputFile.is_open()) { + std::cerr << "Error: Could not open Centroids.txt" << std::endl; + return; + } + + // Data structure to store centroids by histogram and peak number + std::map> centroidData; + + // Read data from the file + std::string line; + while (std::getline(inputFile, line)) { + std::istringstream iss(line); + int histogramIndex, peakNumber; + double centroid; + if (iss >> histogramIndex >> peakNumber >> centroid) { + centroidData[histogramIndex][peakNumber] = centroid; + } + } + + inputFile.close(); + + // Ensure histogram 24 exists and has data + if (centroidData.find(1) == centroidData.end()) { + std::cerr << "Error: Histogram 0 not found in the data!" << std::endl; + return; + } + + // Reference centroids from histogram 24 + const auto& referenceCentroids = centroidData[1]; + std::ofstream outputFile("slope_intercept_results.txt"); + if (!outputFile.is_open()) { + std::cerr << "Error: Could not open the output file for writing!" << std::endl; + return; + } + outputFile << "Histogram Number\tSlope\tIntercept\n"; + // Loop through histograms 25 to 47 + for (int targetHist = 0; targetHist <= 23; targetHist++) { + // Ensure the target histogram exists and matches in peak numbers + if (centroidData.find(targetHist) == centroidData.end() || centroidData[targetHist].size() != referenceCentroids.size()) { + //4th cnetroid data point for 19 was generated using the 3 datqa points for the slope of wires 0 and 19 + std::cout << "Skipping Histogram " << targetHist << " due to mismatched or missing data." << std::endl; + continue; + } + + // Prepare x and y values for TGraph + std::vector xValues, yValues; + for (const auto& [peakNumber, refCentroid] : referenceCentroids) { + if (centroidData[targetHist].find(peakNumber) != centroidData[targetHist].end()) { + yValues.push_back(refCentroid); + xValues.push_back(centroidData[targetHist][peakNumber]); + } else { + std::cerr << "Warning: Peak " << peakNumber << " missing in histogram " << targetHist << std::endl; + } + } + + if (xValues.size() < 3) { + std::cout << "Skipping Histogram " << targetHist << " as it has less than 3 matching centroids." << std::endl; + continue; + } + + // Create a TGraph + TCanvas *c1 = new TCanvas(Form("c_centroid_1_vs_%d", targetHist), Form("Centroid 1 vs %d", targetHist), 800, 600); + TGraph *graph = new TGraph(xValues.size(), &xValues[0], &yValues[0]); + graph->SetTitle(Form("Centroid of Histogram %d vs 1", targetHist)); + graph->GetYaxis()->SetTitle("Centroid of Histogram 1"); + graph->GetXaxis()->SetTitle(Form("Centroid of Histogram %d", targetHist)); + graph->SetMarkerStyle(20); // Full circle marker + graph->SetMarkerSize(1.0); + graph->SetMarkerColor(kBlue); + // Draw the graph + graph->Draw("AP"); + double minX = *std::min_element(xValues.begin(), xValues.end()); + double maxX = *std::max_element(xValues.begin(), xValues.end()); + // Fit the data with a linear function + TF1 *fitLine = new TF1("fitLine", "pol1", minX, maxX); // Adjust range as needed + fitLine->SetLineColor(kRed); // Set the line color to distinguish it + fitLine->SetLineWidth(2); // Thicker line for visibility + graph->Fit(fitLine, "M"); + fitLine->Draw("same"); + fitLine->SetParLimits(0, -10, 10); // Limit intercept between -10 and 10 + fitLine->SetParLimits(1, 0, 2); + // Extract slope and intercept + double slope = fitLine->GetParameter(1); + double intercept = fitLine->GetParameter(0); + outputFile << targetHist << "\t" << slope << "\t" << intercept << "\n"; + std::cout << "Histogram 24 vs " << targetHist << ": Slope = " << slope << ", Intercept = " << intercept << std::endl; + std::vector residuals; + for (size_t i = 0; i < xValues.size(); ++i) { + double fittedY = fitLine->Eval(xValues[i]); // Evaluate fitted function at x + double residual = yValues[i] - fittedY; // Residual = observed - fitted + residuals.push_back(residual); + } + + // Create a graph for the residuals + /*TGraph *residualGraph = new TGraph(residuals.size(), &xValues[0], &residuals[0]); + residualGraph->SetTitle(Form("Residuals for Histogram 24 vs %d", targetHist)); + residualGraph->GetYaxis()->SetTitle("Residuals"); + residualGraph->GetXaxis()->SetTitle(Form("Centroid of Histogram %d", targetHist)); + residualGraph->SetMarkerStyle(20); + residualGraph->SetMarkerSize(1.0); + residualGraph->SetMarkerColor(kGreen); + + // Draw the residuals plot below the original plot (can be on a new canvas if preferred) + TCanvas *c2 = new TCanvas(Form("c_residuals_24_vs_%d", targetHist), Form("Residuals for Centroid 24 vs %d", targetHist), 800, 400); + residualGraph->Draw("AP");*/ + c1->Update(); + //c2->Update(); + std::cout << "Press Enter to continue..." << std::endl; + + //std::cin.get(); + c1->WaitPrimitive(); + //c2->WaitPrimitive(); + //std::cin.get(); + //std::cin.get(); + } + outputFile.close(); + std::cout << "Results written to slope_intercept_results.txt" << std::endl; +} diff --git a/anasen_analysis_vignesh/PCGainMatch.C b/anasen_analysis_vignesh/PCGainMatch.C new file mode 100644 index 0000000..cd86390 --- /dev/null +++ b/anasen_analysis_vignesh/PCGainMatch.C @@ -0,0 +1,454 @@ +#define PCGainMatch_cxx + +#include "PCGainMatch.h" +#include +#include +#include +#include +#include +#include +#include +#include "Armory/ClassSX3.h" +#include "Armory/ClassPW.h" + +#include "TVector3.h" + +TH2F * hsx3IndexVE; +TH2F * hqqqIndexVE; +TH2F * hpcIndexVE; + +TH2F * hsx3Coin; +TH2F * hqqqCoin; +TH2F * hpcCoin; + +TH2F * hqqqPolar; +TH2F * hsx3VpcIndex; +TH2F * hqqqVpcIndex; +TH2F * hqqqVpcE; +TH2F * hsx3VpcE; +TH2F * hanVScatsum; +TH2F * hanVScatsum_a[24]; +TH2F * hanVScatsum_hcut; +TH2F * hanVScatsum_lcut; +TH2F * hAnodeHits; +TH1F * hAnodeMultiplicity; + + +int padID = 0; + +SX3 sx3_contr; +PW pw_contr; +TVector3 hitPos; +bool HitNonZero; + +TH1F * hZProj; +TCutG *AnCatSum_high; +TCutG *AnCatSum_low; +TCutG *PCCoinc_cut1; +TCutG *PCCoinc_cut2; +bool inCuth; +bool inCutl; +bool inPCCut; + +void PCGainMatch::Begin(TTree * /*tree*/){ + TString option = GetOption(); + + hsx3IndexVE = new TH2F("hsx3IndexVE", "SX3 index vs Energy; sx3 index ; Energy", 24*12, 0, 24*12, 400, 0, 5000); hsx3IndexVE->SetNdivisions( -612, "x"); + hqqqIndexVE = new TH2F("hqqqIndexVE", "QQQ index vs Energy; QQQ index ; Energy", 4*2*16, 0, 4*2*16, 400, 0, 5000); hqqqIndexVE->SetNdivisions( -1204, "x"); + hpcIndexVE = new TH2F("hpcIndexVE", "PC index vs Energy; PC index ; Energy", 2*24, 0, 2*24, 800, 0, 16000); hpcIndexVE->SetNdivisions( -1204, "x"); + + + hsx3Coin = new TH2F("hsx3Coin", "SX3 Coincident", 24*12, 0, 24*12, 24*12, 0, 24*12); + hqqqCoin = new TH2F("hqqqCoin", "QQQ Coincident", 4*2*16, 0, 4*2*16, 4*2*16, 0, 4*2*16); + hpcCoin = new TH2F("hpcCoin", "PC Coincident", 2*24, 0, 2*24, 2*24, 0, 2*24); + + hqqqPolar = new TH2F("hqqqPolar", "QQQ Polar ID", 16*4, -TMath::Pi(), TMath::Pi(),16, 10, 50); + + hsx3VpcIndex = new TH2F("hsx3Vpcindex", "sx3 vs pc; sx3 index; pc index", 24*12, 0, 24*12, 48, 0, 48); + hsx3VpcIndex->SetNdivisions( -612, "x"); + hsx3VpcIndex->SetNdivisions( -12, "y"); + hqqqVpcIndex = new TH2F("hqqqVpcindex", "qqq vs pc; qqq index; pc index", 4*2*16, 0, 4*2*16, 48, 0, 48); + hqqqVpcIndex->SetNdivisions( -612, "x"); + hqqqVpcIndex->SetNdivisions( -12, "y"); + + hqqqVpcE = new TH2F("hqqqVpcEnergy", "qqq vs pc; qqq energy; pc energy", 400, 0, 5000, 400, 0, 5000); + hqqqVpcE->SetNdivisions( -612, "x"); + hqqqVpcE->SetNdivisions( -12, "y"); + + hsx3VpcE = new TH2F("hsx3VpcEnergy", "sx3 vs pc; sx3 energy; pc energy", 400, 0, 5000, 400, 0, 5000); + hsx3VpcE->SetNdivisions( -612, "x"); + hsx3VpcE->SetNdivisions( -12, "y"); + + hZProj = new TH1F("hZProj", "Nos of anodes", 20, 0, 19); + hAnodeHits = new TH2F("hAnodeHits", "Anode vs Anode Energy, Anode ID; Anode E", 24,0 , 23, 400, 0 , 20000); + hAnodeMultiplicity = new TH1F("hAnodeMultiplicity", "Number of Anodes/Event", 40, 0, 40); + hanVScatsum = new TH2F("hanVScatsum", "Anode vs Cathode Sum; Anode E; Cathode E", 400,0 , 10000, 800, 0 , 16000); + for (int i = 0; i < 24; i++) { + TString histName = Form("hAnodeVsCathode_%d", i); + TString histTitle = Form("Anode %d vs Cathode Sum; Anode E; Cathode Sum E", i); + hanVScatsum_a[i] = new TH2F(histName, histTitle, 400, 0, 10000, 400, 0, 16000); + } + hanVScatsum_lcut = new TH2F("hanVScatsum_LCUT", "Anode vs Cathode Sum; Anode E; Cathode E", 400,0 , 16000, 400, 0 , 16000); + hanVScatsum_hcut = new TH2F("hanVScatsum_HCUT", "Anode vs Cathode Sum; Anode E; Cathode E", 400,0 , 16000, 400, 0 , 16000); + + sx3_contr.ConstructGeo(); + pw_contr.ConstructGeo(); + // TFile *f1 = new TFile("AnCatSum_high.root"); + // TFile *f2 = new TFile("AnCatSum_low.root"); + // TFile *f3 = new TFile("PCCoinc_cut1.root"); + // TFile *f4 = new TFile("PCCoinc_cut2.root"); + // AnCatSum_high= (TCutG*)f1->Get("AnCatSum_high"); + // AnCatSum_low= (TCutG*)f2->Get("AnCatSum_low"); + // PCCoinc_cut1= (TCutG*)f3->Get("PCCoinc_cut1"); + // PCCoinc_cut2= (TCutG*)f4->Get("PCCoinc_cut2"); +} + + + + +Bool_t PCGainMatch::Process(Long64_t entry){ +// if (entry % 1000000 == 0) { +// std::cout << "Processing entry: " << entry << std::endl; +// } + // if ( entry > 100 ) return kTRUE; + + hitPos.Clear(); + HitNonZero = false; + + // if( entry > 1) return kTRUE; + // printf("################### ev : %llu \n", entry); + + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + // sx3.Print(); + + //########################################################### Raw data + + // //======================= PC + + std::vector> anodeHits={}; + std::vector> cathodeHits={}; + int aID = 0; + int cID = 0; + float aE = 0; + float cE = 0; + +// Define the excluded SX3 and QQQ channels + // std::unordered_set excludeSX3 = {34, 35, 36, 37, 61, 62, 67, 73, 74, 75, 76, 77, 78, 79, 80, 93, 97, 100, 103, 108, 109, 110, 111, 112}; + // std::unordered_set excludeQQQ = {0, 17, 109, 110, 111, 112, 113, 119, 127, 128}; + // inCuth=false; + // inCutl=false; + // inPCCut=false; + for( int i = 0; i < pc.multi; i ++){ + + if(pc.e[i]>50 && pc.multi<7){ + + float aESum = 0; + float cESum = 0; + if (pc.index[i] < 24 ) { + anodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + } else if (pc.index[i] >= 24) { + cathodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + } + + for(int j=i+1;jIsInside(pc.index[i], pc.index[j]) || PCCoinc_cut2->IsInside(pc.index[i], pc.index[j])){ + // // hpcCoin->Fill(pc.index[i], pc.index[j]); + // inPCCut = true; + // } + hpcCoin->Fill(pc.index[i], pc.index[j]); + } + if (anodeHits.size()==1 && cathodeHits.size() >= 1) { + + for (const auto& anode : anodeHits) { + // for(int l=0; lcEMax){ + // cEMax = cE; + // cIDMax = cID; + // } + // if(cE>cEnextMax && cEIsInside(pc.index[i], pc.index[j]) || PCCoinc_cut2->IsInside(pc.index[i], pc.index[j])){ + // // hpcCoin->Fill(pc.index[i], pc.index[j]); + // inPCCut = true; + // } + // hpcCoin->Fill(pc.index[i], pc.index[j]); + // } + + // Check if the accumulated energies are within the defined ranges + // if (AnCatSum_high && AnCatSum_high->IsInside(aESum, cESum)) { + // inCuth = true; + // } + // if (AnCatSum_low && AnCatSum_low->IsInside(aESum, cESum)) { + // inCutl = true; + // } + + // Fill histograms based on the cut conditions + // if (inCuth && inPCCut) { + // hanVScatsum_hcut->Fill(aESum, cESum); + // } + // if (inCutl && inPCCut) { + // hanVScatsum_lcut->Fill(aESum, cESum); + // } + // for(auto anode : anodeHits){ + + // float aE = anode.second; + // aESum += aE; + // if(inPCCut){ + hanVScatsum->Fill(aESum, cESum); + // } + if (aID < 24 && aE > 50) { + hanVScatsum_a[aID]->Fill(aE, cESum); + } + + + // } + // Fill histograms for the `pc` data + hpcIndexVE->Fill(pc.index[i], pc.e[i]); + // if(inPCCut){ + hAnodeMultiplicity->Fill(anodeHits.size()); + // } + } + + } + } + + + + // //======================= SX3 + + std::vector> ID; // first = id, 2nd = index + for( int i = 0; i < sx3.multi; i ++){ + if(sx3.e[i]>50){ + ID.push_back(std::pair(sx3.id[i], i)); + hsx3IndexVE->Fill( sx3.index[i], sx3.e[i] ); + + for( int j = i+1; j < sx3.multi; j++){ + hsx3Coin->Fill( sx3.index[i], sx3.index[j]); + } + + for( int j = 0; j < pc.multi; j++){ + hsx3VpcIndex->Fill( sx3.index[i], pc.index[j] ); + // if( sx3.ch[index] > 8 ){ + // hsx3VpcE->Fill( sx3.e[i], pc.e[j] ); + // } + } + } + } + + + if( ID.size() > 0 ){ + std::sort(ID.begin(), ID.end(), [](const std::pair & a, const std::pair & b) { + return a.first < b.first; + } ); + // printf("##############################\n"); + // for( size_t i = 0; i < ID.size(); i++) printf("%zu | %d %d \n", i, ID[i].first, ID[i].second ); + + std::vector> sx3ID; + sx3ID.push_back(ID[0]); + bool found = false; + for( size_t i = 1; i < ID.size(); i++){ + if( ID[i].first == sx3ID.back().first) { + sx3ID.push_back(ID[i]); + if( sx3ID.size() >= 3) { + found = true; + } + }else{ + if( !found ){ + sx3ID.clear(); + sx3ID.push_back(ID[i]); + } + } + } + + // printf("---------- sx3ID Multi : %zu \n", sx3ID.size()); + + if( found ){ + int sx3ChUp, sx3ChDn, sx3ChBk; + float sx3EUp, sx3EDn; + // printf("------ sx3 ID : %d, multi: %zu\n", sx3ID[0].first, sx3ID.size()); + for( size_t i = 0; i < sx3ID.size(); i++ ){ + int index = sx3ID[i].second; + // printf(" %zu | index %d | ch : %d, energy : %d \n", i, index, sx3.ch[index], sx3.e[index]); + + + if( sx3.ch[index] < 8 ){ + if( sx3.ch[index] % 2 == 0) { + sx3ChDn = sx3.ch[index]; + sx3EDn = sx3.e[index]; + }else{ + sx3ChUp = sx3.ch[index]; + sx3EUp = sx3.e[index]; + } + }else{ + sx3ChBk = sx3.ch[index]; + } + for( int j = 0; j < pc.multi; j++){ + + // hsx3VpcIndex->Fill( sx3.index[i], pc.index[j] ); + if( sx3.ch[index] > 8 && pc.index[j]<24 && pc.e[j]>50 ){ + hsx3VpcE->Fill( sx3.e[i], pc.e[j] ); + // hpcIndexVE->Fill( pc.index[i], pc.e[i] ); + } + } + } + + sx3_contr.CalSX3Pos(sx3ID[0].first, sx3ChUp, sx3ChDn, sx3ChBk, sx3EUp, sx3EDn); + hitPos = sx3_contr.GetHitPos(); + HitNonZero = true; + // hitPos.Print(); + } + + } + + + // //======================= QQQ + for( int i = 0; i < qqq.multi; i ++){ + + // for( int j = 0; j < pc.multi; j++){ + if(qqq.e[i]>50 ){ + hqqqIndexVE->Fill( qqq.index[i], qqq.e[i] ); + for( int j = 0; j < qqq.multi; j++){ + if ( j == i ) continue; + hqqqCoin->Fill( qqq.index[i], qqq.index[j]); + } + + + for( int j = i + 1; j < qqq.multi; j++){ + for( int k = 0; k < pc.multi; k++){ + // if(qqq.e[i>50]){ + hqqqVpcE->Fill( qqq.e[i], pc.e[k] ); + hqqqVpcIndex->Fill( qqq.index[i], pc.index[j] ); + } + // } + } + } + // } + } + + // hanVScatsum->Fill(aE,cE); + + + if( HitNonZero){ + pw_contr.CalTrack( hitPos, aID, cID); + hZProj->Fill(pw_contr.GetZ0()); + } + + + + + + + //########################################################### Track constrcution + + + //############################## DO THE KINEMATICS + + + return kTRUE; +} + +void PCGainMatch::Terminate(){ + + gStyle->SetOptStat("neiou"); + TCanvas * canvas = new TCanvas("cANASEN", "ANASEN", 2000, 2000); + canvas->Divide(3,3); + + //hsx3VpcIndex->Draw("colz"); + + //=============================================== pad-1 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hsx3IndexVE->Draw("colz"); + + //=============================================== pad-2 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hqqqIndexVE->Draw("colz"); + + //=============================================== pad-3 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hpcIndexVE->Draw("colz"); + + //=============================================== pad-4 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hsx3Coin->Draw("colz"); + + //=============================================== pad-5 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + canvas->cd(padID)->SetLogz(true); + + hqqqCoin->Draw("colz"); + + //=============================================== pad-6 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + hpcCoin->Draw("colz"); + + //=============================================== pad-7 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + // hsx3VpcIndex ->Draw("colz"); + hsx3VpcE->Draw("colz") ; + + //=============================================== pad-8 + padID ++; canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + + // hqqqVpcIndex ->Draw("colz"); + + hqqqVpcE ->Draw("colz"); + //=============================================== pad-9 + padID ++; + + // canvas->cd(padID)->DrawFrame(-50, -50, 50, 50); + // hqqqPolar->Draw("same colz pol"); + + canvas->cd(padID); canvas->cd(padID)->SetGrid(1); + hanVScatsum->Draw("colz"); + // hAnodeHits->Draw("colz"); + // hAnodeMultiplicity->Draw(); +} diff --git a/anasen_analysis_vignesh/PCGainMatch.h b/anasen_analysis_vignesh/PCGainMatch.h new file mode 100644 index 0000000..8066289 --- /dev/null +++ b/anasen_analysis_vignesh/PCGainMatch.h @@ -0,0 +1,114 @@ +#ifndef PCGainMatch_h +#define PCGainMatch_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class PCGainMatch : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + + PCGainMatch(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~PCGainMatch() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(PCGainMatch,0); +}; + +#endif + +#ifdef PCGainMatch_cxx +void PCGainMatch::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + +} + +Bool_t PCGainMatch::Notify(){ + + return kTRUE; +} + +void PCGainMatch::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void PCGainMatch::SlaveTerminate(){ + +} + + +#endif // #ifdef Analyzer_cxx diff --git a/anasen_analysis_vignesh/PreAnalysis.C b/anasen_analysis_vignesh/PreAnalysis.C new file mode 100644 index 0000000..a3bcf70 --- /dev/null +++ b/anasen_analysis_vignesh/PreAnalysis.C @@ -0,0 +1,82 @@ +#define PreAnalysis_cxx + +#include "PreAnalysis.h" +#include +#include +#include +#include + +#include "mapping.h" + +TH2F ** hRate; +TH2F ** hEnergy; + + +int padID = 0; + +void PreAnalysis::Begin(TTree * /*tree*/){ + TString option = GetOption(); + + //Find the first and last timestamp, to get the run duration + + hRate = new TH2F * [nBd]; + hEnergy = new TH2F * [nBd]; + for( int i = 0; i < nBd; i++){ + if( board.at(i) > 1000) { + hRate[i] = new TH2F(Form("hRate%d", board.at(i)), Form("Digi-%d; ch; sec", board.at(i)), 64, 0, 64, 100, 0, 100); + hEnergy[i] = new TH2F(Form("hEnergy%d", board.at(i)), Form("Digi-%d; ch; raw E", board.at(i)), 64, 0, 64, 400, 0, 5000); + }else{ + hRate[i] = new TH2F(Form("hRate%d", board.at(i)), Form("Digi-%d; ch; sec", board.at(i)), 16, 0, 16, 100, 0, 100); + hEnergy[i] = new TH2F(Form("hEnergy%d", board.at(i)), Form("Digi-%d; ch; raw E", board.at(i)), 16, 0, 16, 400, 0, 5000); + } + } + + printf("================================ done creating histograms.\n"); + +} + +Bool_t PreAnalysis::Process(Long64_t entry){ + + b_multi->GetEntry(entry); + b_sn->GetEntry(entry); + b_ch->GetEntry(entry); + b_e->GetEntry(entry); + b_e_t->GetEntry(entry); + + // printf("------------- multi: %lu\n", multi); + + for( unsigned int i = 0; i < multi; i++){ + + for( int j = 0; j < nBd; j++ ){ + + if( sn[i] == board.at(j) ) { + hRate[j]->Fill(ch[i], e_t[i]/1e9); + + hEnergy[j]->Fill(ch[i], e[i]); + break; + } + } + } + + return kTRUE; +} + +void PreAnalysis::Terminate(){ + + printf("================================ %s\n", __func__); + + gStyle->SetOptStat("neiou"); + TCanvas * canvas = new TCanvas("cANASEN", "Pre-Analysis, ANASEN", 4000, 800); + canvas->Divide(10,2); + + for( int i = 0; i < nBd; i++){ + padID++; canvas->cd(padID); + hRate[i]->Draw("colz"); + } + + for( int i = 0; i < nBd; i++){ + padID++; canvas->cd(padID); + hEnergy[i]->Draw("colz"); + } + +} diff --git a/anasen_analysis_vignesh/PreAnalysis.h b/anasen_analysis_vignesh/PreAnalysis.h new file mode 100644 index 0000000..373f21b --- /dev/null +++ b/anasen_analysis_vignesh/PreAnalysis.h @@ -0,0 +1,92 @@ +#ifndef PreAnalysis_h +#define PreAnalysis_h + +#include +#include +#include +#include + +#define MAXMULTI 1000 + +class PreAnalysis : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + + // Declaration of leaf types + ULong64_t evID; + UInt_t multi; + UShort_t sn[MAXMULTI]; //[multi] + UShort_t ch[MAXMULTI]; //[multi] + UShort_t e[MAXMULTI]; //[multi] + UShort_t e2[MAXMULTI]; //[multi] + ULong64_t e_t[MAXMULTI]; //[multi] + UShort_t e_f[MAXMULTI]; //[multi] + Bool_t pileUp[MAXMULTI]; //[multi] + + // List of branches + TBranch *b_event_ID; //! + TBranch *b_multi; //! + TBranch *b_sn; //! + TBranch *b_ch; //! + TBranch *b_e; //! + TBranch *b_e2; //! + TBranch *b_e_t; //! + TBranch *b_e_f; //! + TBranch *b_pileUp; //! + + PreAnalysis(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~PreAnalysis() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(PreAnalysis,0); +}; + +#endif + +#ifdef PreAnalysis_cxx +void PreAnalysis::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_event_ID); + fChain->SetBranchAddress("multi", &multi, &b_multi); + fChain->SetBranchAddress("sn", sn, &b_sn); + fChain->SetBranchAddress("ch", ch, &b_ch); + fChain->SetBranchAddress("e", e, &b_e); + fChain->SetBranchAddress("e2", e2, &b_e2); + fChain->SetBranchAddress("e_t", e_t, &b_e_t); + fChain->SetBranchAddress("e_f", e_f, &b_e_f); + fChain->SetBranchAddress("pileUp", pileUp, &b_pileUp); +} + +Bool_t PreAnalysis::Notify(){ + + return kTRUE; +} + +void PreAnalysis::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void PreAnalysis::SlaveTerminate(){ + +} + +#endif // #ifdef PreAnalysis_cxx diff --git a/anasen_analysis_vignesh/ProcessRun.sh b/anasen_analysis_vignesh/ProcessRun.sh new file mode 100755 index 0000000..64ce829 --- /dev/null +++ b/anasen_analysis_vignesh/ProcessRun.sh @@ -0,0 +1,34 @@ +#!/bin/bash + +if [ "$#" -ne 3 ]; then + echo "Usage: $0 runID timeWindow_ns option" + echo "option: 0 - process raw data, 1 - process mapped data" + echo "Exiting..." + exit 1 +fi + +runID=$1 +timeWindow=$2 + +option=$3 + +# rawFolder=/home/tandem/data1/2024_09_17Fap/data +rawFolder=../Raw_data +rootFolder=../root_data + +if [ $option -eq 0 ]; then + + # rsync -auh --info=progress2 splitpole@128.186.111.223:/media/nvmeData/2024_09_17Fap/*.fsu /home/tandem/data1/2024_09_17Fap/data + + fileList=`\ls -1 ${rawFolder}/*Run_${runID}_*.fsu` + + # ./EventBuilder ${timeWindow} 0 0 100000000 ${fileList} + + outFile=${rawFolder}/*${runID}*${timeWindow}.root + + mv -vf ${outFile} ${rootFolder}/. + + ./Mapper ${rootFolder}/*${runID}*${timeWindow}.root +fi + +root "processRun.C(\"${rootFolder}/Run_${runID}_mapped.root\")" diff --git a/anasen_analysis_vignesh/QQQ_Calcheck.C b/anasen_analysis_vignesh/QQQ_Calcheck.C new file mode 100644 index 0000000..f7347ec --- /dev/null +++ b/anasen_analysis_vignesh/QQQ_Calcheck.C @@ -0,0 +1,167 @@ + +#define QQQ_Calcheck_cxx + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "Armory/HistPlotter.h" +#include "TVector3.h" +#include "QQQ_Calcheck.h" + +TH2F *hQQQFVB; +HistPlotter *plotter; +int padID = 0; + +TCutG *cut; +std::map, std::vector>> dataPoints; + +bool qqqEcut = false; + +// Gain Arrays +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqwGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +double qqqrGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqwGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +bool qqqrGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; + +void QQQ_Calcheck::Begin(TTree * /*tree*/) +{ + plotter = new HistPlotter("Cal_checkQQQ.root", "TFILE"); + // ----------------------- Load QQQ Gains + { + std::string filename = "qqq_GainMatch.dat"; + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + } + else + { + int det, ring, wedge; + double gainw,gainr; + while (infile >> det >> ring >> wedge >> gainw>> gainr) + { + qqqwGain[det][ring][wedge] = gainw; + // qqqrGain[det][ring][wedge] = gainr; + qqqwGainValid[det][ring][wedge] = (gainw > 0); + // qqqrGainValid[det][ring][wedge] = (gainr > 0); + } + infile.close(); + std::cout << "Loaded QQQ gains from " << filename << std::endl; + } + } + // ----------------------- Load QQQ Calibrations + { + std::string filename = "qqq_Calib.dat"; + std::ifstream infile(filename); + if (!infile.is_open()) + { + std::cerr << "Error opening " << filename << "!" << std::endl; + } + else + { + int det, ring, wedge; + double slope; + while (infile >> det >> ring >> wedge >> slope) + { + qqqCalib[det][ring][wedge] = slope; + qqqCalibValid[det][ring][wedge] = (slope > 0); + } + infile.close(); + std::cout << "Loaded QQQ calibrations from " << filename << std::endl; + } + } +} + +Bool_t QQQ_Calcheck::Process(Long64_t entry) +{ + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + + qqq.CalIndex(); + + for (int i = 0; i < qqq.multi; i++) + { + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.e[i] > 100) + qqqEcut = true; + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + float eWedgeRaw = 0.0; + float eWedge = 0.0; + float eWedgeMeV = 0.0; + float eRingRaw = 0.0; + float eRing = 0.0; + float eRingMeV = 0.0; + // plug in gains + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && /*qqqrGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16] &&*/ qqqwGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedgeRaw = qqq.e[i]; + eWedge = qqq.e[i] * qqqwGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + // printf("Wedge E: %.2f Gain: %.4f \n", eWedge, qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]); + chRing = qqq.ch[j] - 16; + eRingRaw = qqq.e[j]; + eRing = qqq.e[j];//* qqqrGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i]-16]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16/* && qqqrGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16] */&& qqqwGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqwGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + eWedgeRaw = qqq.e[j]; + + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i];// * qqqrGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + eRingRaw = qqq.e[i]; + } + else + continue; + // plug in calibrations + if (qqqCalibValid[qqq.id[i]][chWedge][chRing]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + } + else + continue; + + // hQQQFVB->Fill(eWedge, eRing); + plotter->Fill2D(Form("hRaw_qqq%d_ring%d_wedge%d", qqq.id[i], chRing, chWedge), 400, 0, 8000, 400, 0, 8000, eWedgeRaw, eRingRaw, "ERaw"); + plotter->Fill2D(Form("hGM_qqq%d_ring%d_wedge%d", qqq.id[i], chRing, chWedge), 400, 0, 16000, 400, 0, 16000, eWedge, eRing, "EGM"); + plotter->Fill2D(Form("hCal_qqq%d_ring%d_wedge%d", qqq.id[i], chRing, chWedge), 400, 0, 10, 400, 0, 10, eWedgeMeV, eRingMeV, "ECal"); + if(eWedgeRaw >1500 && eRingRaw>1500 ) + plotter->Fill2D(Form("hCal_cut_qqq%d_ring%d_wedge%d", qqq.id[i], chRing, chWedge), 400, 0, 10, 400, 0, 10, eWedgeMeV, eRingMeV, "ECal_cut"); + + plotter->Fill2D(Form("hRCal_qqq%d", qqq.id[i]), 16, 0, 15, 1000, 0, 30, chRing, eRingMeV, "RingCal"); + plotter->Fill2D(Form("hWCal_qqq%d", qqq.id[i]), 16, 0, 15, 1000, 0, 30, chWedge, eWedgeMeV, "WedgeCal"); + plotter->Fill2D("hRawQQQ", 4000, 0, 8000, 4000, 0, 8000, eWedgeRaw, eRingRaw); + plotter->Fill2D("hGMQQQ", 4000, 0, 8000, 4000, 0, 8000, eWedge, eRing); + plotter->Fill2D("hCalQQQ", 4000, 0, 10, 4000, 0, 10, eWedgeMeV, eRingMeV); + } + } + } + + return kTRUE; +} + +void QQQ_Calcheck::Terminate() +{ + plotter->FlushToDisk(); + std::cout << "Calibration check file for 2D QQQ histogram saved.\n"; +} diff --git a/anasen_analysis_vignesh/QQQ_Calcheck.h b/anasen_analysis_vignesh/QQQ_Calcheck.h new file mode 100644 index 0000000..90fdaca --- /dev/null +++ b/anasen_analysis_vignesh/QQQ_Calcheck.h @@ -0,0 +1,114 @@ +#ifndef QQQ_Calcheck_h +#define QQQ_Calcheck_h + +#include +#include +#include +#include + +#include "Armory/ClassDet.h" + +class QQQ_Calcheck : public TSelector { +public : + TTree *fChain; //!pointer to the analyzed TTree or TChain + +// Fixed size dimensions of array or collections stored in the TTree if any. + + // Declaration of leaf types + Det sx3; + Det qqq; + Det pc ; + + ULong64_t evID; + UInt_t run; + + // List of branches + TBranch *b_eventID; //! + TBranch *b_run; //! + TBranch *b_sx3Multi; //! + TBranch *b_sx3ID; //! + TBranch *b_sx3Ch; //! + TBranch *b_sx3E; //! + TBranch *b_sx3T; //! + TBranch *b_qqqMulti; //! + TBranch *b_qqqID; //! + TBranch *b_qqqCh; //! + TBranch *b_qqqE; //! + TBranch *b_qqqT; //! + TBranch *b_pcMulti; //! + TBranch *b_pcID; //! + TBranch *b_pcCh; //! + TBranch *b_pcE; //! + TBranch *b_pcT; //! + + QQQ_Calcheck(TTree * /*tree*/ =0) : fChain(0) { } + virtual ~QQQ_Calcheck() { } + virtual Int_t Version() const { return 2; } + virtual void Begin(TTree *tree); + virtual void SlaveBegin(TTree *tree); + virtual void Init(TTree *tree); + virtual Bool_t Notify(); + virtual Bool_t Process(Long64_t entry); + virtual Int_t GetEntry(Long64_t entry, Int_t getall = 0) { return fChain ? fChain->GetTree()->GetEntry(entry, getall) : 0; } + virtual void SetOption(const char *option) { fOption = option; } + virtual void SetObject(TObject *obj) { fObject = obj; } + virtual void SetInputList(TList *input) { fInput = input; } + virtual TList *GetOutputList() const { return fOutput; } + virtual void SlaveTerminate(); + virtual void Terminate(); + + ClassDef(QQQ_Calcheck,0); +}; + +#endif + +#ifdef QQQ_Calcheck_cxx +void QQQ_Calcheck::Init(TTree *tree){ + + // Set branch addresses and branch pointers + if (!tree) return; + fChain = tree; + fChain->SetMakeClass(1); + + fChain->SetBranchAddress("evID", &evID, &b_eventID); + fChain->SetBranchAddress("run", &run, &b_run); + + sx3.SetDetDimension(24,12); + qqq.SetDetDimension(4,32); + pc.SetDetDimension(2,24); + + fChain->SetBranchAddress("sx3Multi", &sx3.multi, &b_sx3Multi); + fChain->SetBranchAddress("sx3ID", &sx3.id, &b_sx3ID); + fChain->SetBranchAddress("sx3Ch", &sx3.ch, &b_sx3Ch); + fChain->SetBranchAddress("sx3E", &sx3.e, &b_sx3E); + fChain->SetBranchAddress("sx3T", &sx3.t, &b_sx3T); + fChain->SetBranchAddress("qqqMulti", &qqq.multi, &b_qqqMulti); + fChain->SetBranchAddress("qqqID", &qqq.id, &b_qqqID); + fChain->SetBranchAddress("qqqCh", &qqq.ch, &b_qqqCh); + fChain->SetBranchAddress("qqqE", &qqq.e, &b_qqqE); + fChain->SetBranchAddress("qqqT", &qqq.t, &b_qqqT); + fChain->SetBranchAddress("pcMulti", &pc.multi, &b_pcMulti); + fChain->SetBranchAddress("pcID", &pc.id, &b_pcID); + fChain->SetBranchAddress("pcCh", &pc.ch, &b_pcCh); + fChain->SetBranchAddress("pcE", &pc.e, &b_pcE); + fChain->SetBranchAddress("pcT", &pc.t, &b_pcT); + +} + +Bool_t QQQ_Calcheck::Notify(){ + + return kTRUE; +} + +void QQQ_Calcheck::SlaveBegin(TTree * /*tree*/){ + + TString option = GetOption(); + +} + +void QQQ_Calcheck::SlaveTerminate(){ + +} + + +#endif // #ifdef QQQ_Calcheck_cxx \ No newline at end of file diff --git a/anasen_analysis_vignesh/TrackRecon.C.backup b/anasen_analysis_vignesh/TrackRecon.C.backup new file mode 100644 index 0000000..c5e169a --- /dev/null +++ b/anasen_analysis_vignesh/TrackRecon.C.backup @@ -0,0 +1,742 @@ +#define TrackRecon_cxx + +#include "TrackRecon.h" +#include "Armory/ClassPW.h" +#include "Armory/HistPlotter.h" + +#include +#include +#include +#include +#include +#include "TVector3.h" + +#include +#include +#include +#include +#include +#include + +// Global instances +PW pw_contr; +PW pwinstance; +TVector3 hitPos; + +struct Event { + TVector3 pos; + double Energy1=-1; //Front for QQQ, Anode for PC + double Energy2=-1; //Back for QQQ, Cathode for PC + double Time1=-1; + double Time2=-1; +}; + +// Calibration globals +const int MAX_QQQ = 4; +const int MAX_RING = 16; +const int MAX_WEDGE = 16; +double qqqGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}}; +bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}}; +// TCutg *cutQQQ; + +// PC Arrays +double pcSlope[48]; +double pcIntercept[48]; + +HistPlotter *plotter; + +bool HitNonZero; +bool sx3ecut; +bool qqqEcut; + +void TrackRecon::Begin(TTree * /*tree*/) +{ + TString option = GetOption(); + plotter = new HistPlotter("Analyzer_QQQ.root", "TFILE"); + + pw_contr.ConstructGeo(); + pwinstance.ConstructGeo(); + + // --------------------------------------------------------- + // 1. CRITICAL FIX: Initialize PC Arrays to Default (Raw) + // --------------------------------------------------------- + for (int i = 0; i < 48; i++) + { + pcSlope[i] = 1.0; // Default slope = 1 (preserves Raw energy) + pcIntercept[i] = 0.0; // Default intercept = 0 + } + + // Calculate Crossover Geometry ONCE + TVector3 a, c, diff; + double a2, ac, c2, adiff, cdiff, denom, alpha; + + for (size_t i = 0; i < pwinstance.An.size(); i++) + { + a = pwinstance.An[i].first - pwinstance.An[i].second; + + for (size_t j = 0; j < pwinstance.Ca.size(); j++) + { + c = pwinstance.Ca[j].first - pwinstance.Ca[j].second; + diff = pwinstance.An[i].first - pwinstance.Ca[j].first; + a2 = a.Dot(a); + c2 = c.Dot(c); + ac = a.Dot(c); + adiff = a.Dot(diff); + cdiff = c.Dot(diff); + denom = a2 * c2 - ac * ac; + alpha = (ac * cdiff - c2 * adiff) / denom; + + Crossover[i][j][0].x = pwinstance.An[i].first.X() + alpha * a.X(); + Crossover[i][j][0].y = pwinstance.An[i].first.Y() + alpha * a.Y(); + Crossover[i][j][0].z = pwinstance.An[i].first.Z() + alpha * a.Z(); + + if (Crossover[i][j][0].z < -190 || Crossover[i][j][0].z > 190 || (i+j)%24 == 12) + { + Crossover[i][j][0].z = 9999999; + } + + Crossover[i][j][1].x = alpha; + Crossover[i][j][1].y = 0; + } + } + + // Load PC Calibrations + std::ifstream inputFile("slope_intercept_results.txt"); + if (inputFile.is_open()) + { + std::string line; + int index; + double slope, intercept; + while (std::getline(inputFile, line)) + { + std::stringstream ss(line); + ss >> index >> slope >> intercept; + if (index >= 0 && index <= 47) + { + pcSlope[index] = slope; + pcIntercept[index] = intercept; + } + } + inputFile.close(); + } + else + { + std::cerr << "Error opening slope_intercept.txt" << std::endl; + } + + // Load QQQ Cuts from file + // { + // std::string filename = "QQQ_PCCut.root"; + // TFile *cutFile = TFile::Open(filename.c_str(), "READ"); + // if (cutFile && !cutFile->IsZombie()) + // { + // cutQQQ = (TCutg *)cutFile->Get("cutQQQPC"); + // if (cutQQQ) + // { + // std::cout << "Loaded QQQ PC cut from " << filename << std::endl; + // } + // else + // { + // std::cerr << "Error: cutQQQPC not found in " << filename << std::endl; + // } + // cutFile->Close(); + // } + // } + + // ... (Load QQQ Gains and Calibs - same as before) ... + { + std::string filename = "qqq_GainMatch.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double gainw, gainr; + while (infile >> det >> wedge >> ring >> gainw >> gainr) + { + qqqGain[det][wedge][ring] = gainw; + qqqGainValid[det][wedge][ring] = (gainw > 0); + // std::cout << "QQQ Gain Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " GainW " << gainw << " GainR " << gainr << std::endl; + } + infile.close(); + } + } + { + std::string filename = "qqq_Calib.dat"; + std::ifstream infile(filename); + if (infile.is_open()) + { + int det, ring, wedge; + double slope; + while (infile >> det >> wedge >> ring >> slope) + { + qqqCalib[det][wedge][ring] = slope; + qqqCalibValid[det][wedge][ring] = (slope > 0); + // std::cout << "QQQ Calib Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " Slope " << slope << std::endl; + } + infile.close(); + } + } +} + +Bool_t TrackRecon::Process(Long64_t entry) +{ + hitPos.Clear(); + HitNonZero = false; + bool qqq1000cut = false; + b_sx3Multi->GetEntry(entry); + b_sx3ID->GetEntry(entry); + b_sx3Ch->GetEntry(entry); + b_sx3E->GetEntry(entry); + b_sx3T->GetEntry(entry); + b_qqqMulti->GetEntry(entry); + b_qqqID->GetEntry(entry); + b_qqqCh->GetEntry(entry); + b_qqqE->GetEntry(entry); + b_qqqT->GetEntry(entry); + b_pcMulti->GetEntry(entry); + b_pcID->GetEntry(entry); + b_pcCh->GetEntry(entry); + b_pcE->GetEntry(entry); + b_pcT->GetEntry(entry); + + sx3.CalIndex(); + qqq.CalIndex(); + pc.CalIndex(); + + // QQQ Processing + + int qqqCount = 0; + int qqqAdjCh = 0; + // REMOVE WHEN RERUNNING USING THE NEW CALIBRATION FILE + for (int i = 0; i < qqq.multi; i++) + { + if ((qqq.id[i] == 3 || qqq.id[i] == 1) && qqq.ch[i] < 16) + { + qqq.ch[i] = 16 - qqq.ch[i]; + } + } + for (int i = 0; i < qqq.multi; i++) + { + if (qqq.id[i] == 0 && qqq.ch[i] >= 16) + { + qqq.ch[i] = 31 - qqq.ch[i] + 16; + } + } + + + + std::vector QQQ_Events, PC_Events; + std::vector QQQ_Events_Raw, PC_Events_Raw; + + + bool PCQQQTimeCut = false; + for (int i = 0; i < qqq.multi; i++) + { + + plotter->Fill2D("QQQ_Index_Vs_Energy", 16 * 8, 0, 16 * 8, 2000, 0, 16000, qqq.index[i], qqq.e[i], "hRawQQQ"); + + for (int j = 0; j < qqq.multi; j++) + { + if (j == i) + continue; + plotter->Fill2D("QQQ_Coincidence_Matrix", 16 * 8, 0, 16 * 8, 16 * 8, 0, 16 * 8, qqq.index[i], qqq.index[j], "hRawQQQ"); + } + + for (int k = 0; k < pc.multi; k++) + { + if (pc.index[k] < 24 && pc.e[k] > 50) + { + plotter->Fill2D("QQQ_Vs_Anode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + plotter->Fill2D("QQQ_Vs_PC_Index", 16 * 8, 0, 16 * 8, 24, 0, 24, qqq.index[i], pc.index[k], "hRawQQQ"); + } + else if (pc.index[k] >= 24 && pc.e[k] > 50) + { + plotter->Fill2D("QQQ_Vs_Cathode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ"); + } + } + + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + qqqCount++; + + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + double tWedge = 0.0; + + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + tWedge = static_cast(qqq.t[i]); + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + eRing = qqq.e[i]; + tRing = static_cast(qqq.t[i]); + tWedge = static_cast(qqq.t[j]); + } + else + continue; + + plotter->Fill1D("Wedgetime_Vs_Ringtime", 100, -1000, 1000, tWedge - tRing, "hTiming"); + plotter->Fill2D("RingE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chRing + qqq.id[i] * 16, eRing, "hRawQQQ"); + plotter->Fill2D("WedgeE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chWedge + qqq.id[i] * 16, eWedge, "hRawQQQ"); + + if (qqqCalibValid[qqq.id[i]][chWedge][chRing]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000; + } + else + continue; + + plotter->Fill2D("WedgeE_Vs_RingECal", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ"); + + for (int k = 0; k < pc.multi; k++) + { + plotter->Fill2D("RingCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Anode_Index" + std::to_string(qqq.id[i]), 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k]); + plotter->Fill2D("RingCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + plotter->Fill2D("WedgeCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ"); + + if (pc.index[k] < 24 && pc.e[k] > 50) + { + // plotter->Fill2D("QQQ_CalibW_Vs_PC_Energy", 1000, 0, 16, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hCalQQQ"); + // plotter->Fill2D("QQQ_CalibR_Vs_PC_Energy", 1000, 0, 16, 2000, 0, 30000, eRingMeV, pc.e[k], "hCalQQQ"); + + // if (tRing - static_cast(pc.t[k]) < 0 && tRing - static_cast(pc.t[k]) > -600) + // // { + // // plotter->Fill2D("QQQ_CalibW_Vs_PC_Energy_Tight", 1000, 0, 16, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hCalQQQ"); + // // plotter->Fill2D("QQQ_CalibR_Vs_PC_Energy_Tight", 1000, 0, 16, 2000, 0, 30000, eRingMeV, pc.e[k], "hCalQQQ"); + // // } + // // else + // // { + // // plotter->Fill2D("QQQ_CalibW_Vs_PC_Energy_OffTime", 1000, 0, 16, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hCalQQQ"); + // // plotter->Fill2D("QQQ_CalibR_Vs_PC_Energy_OffTime", 1000, 0, 16, 2000, 0, 30000, eRingMeV, pc.e[k], "hCalQQQ"); + // // } + plotter->Fill2D("Timing_Difference_QQQ_PC", 500, -1000, 1000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + plotter->Fill2D("DelT_Vs_QQQRingECal", 500, -1000, 1000, 1000, 0, 10, tRing - static_cast(pc.t[k]), eRingMeV, "hTiming"); + plotter->Fill2D("CalibratedQQQEvsPCE_R", 1000, 0, 10, 2000, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ"); + plotter->Fill2D("CalibratedQQQEvsPCE_W", 1000, 0, 10, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ"); + if (tRing - static_cast(pc.t[k]) < -150 && tRing - static_cast(pc.t[k]) > -450) // 27Al + //if (tRing - static_cast(pc.t[k]) < -70 && tRing - static_cast(pc.t[k]) > -150) // 17F + { + PCQQQTimeCut = true; + } + } + + if (pc.index[k] >= 24 && pc.e[k] > 50) { + plotter->Fill2D("Timing_Difference_QQQ_PC_Cathode", 500, -1000, 1000, 16, 0, 16, tRing - static_cast(pc.t[k]), chRing, "hTiming"); + } + } //end of pc loop + + double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + double rho = 50. + 40. / 16. * (chRing + 0.5); + + //Event qqqevent(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),23+75+30), eRingMeV, eWedgeMeV, tRing, tWedge); + //Event qqqeventr(TVector3(rho*TMath::Cos(theta),rho*TMath::Sin(theta),23+75+30), eRing, eWedge, tRing, tWedge); + //QQQ_Events.push_back(qqqevent); + //QQQ_Events_Raw.push_back(qqqeventr); + plotter->Fill2D("QQQPolarPlot", 16 * 4, -TMath::Pi(), TMath::Pi(), 32, 40, 100, theta, rho, "hCalQQQ"); + plotter->Fill2D("QQQCartesianPlot", 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + plotter->Fill2D("QQQCartesianPlot" + std::to_string(qqq.id[i]), 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ"); + if (PCQQQTimeCut) + { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ"); + + if (!HitNonZero) + { + double x = rho * TMath::Cos(theta); + double y = rho * TMath::Sin(theta); + hitPos.SetXYZ(x, y, 23 + 75 + 30); + HitNonZero = true; + } + } + } + } + + plotter->Fill1D("QQQ_Multiplicity", 10, 0, 10, qqqCount, "hRawQQQ"); + + // PC Gain Matching and Filling + double anodeT = -99999; + double cathodeT = 99999; + int anodeIndex = -1; + int cathodeIndex = -1; + for (int i = 0; i < pc.multi; i++) + { + if (pc.e[i] > 10) + { + plotter->Fill2D("PC_Index_Vs_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], static_cast(pc.e[i]), "hRawPC"); + } + + if (pc.index[i] < 48) + { + pc.e[i] = pcSlope[pc.index[i]] * pc.e[i] + pcIntercept[pc.index[i]]; + plotter->Fill2D("PC_Index_VS_GainMatched_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], pc.e[i], "hGMPC"); + } + + if (pc.index[i] < 24) + { + anodeT = static_cast(pc.t[i]); + anodeIndex = pc.index[i]; + } + else + { + cathodeT = static_cast(pc.t[i]); + cathodeIndex = pc.index[i] - 24; + } + + if (anodeT != -99999 && cathodeT != 99999) + { + for (int j = 0; j < qqq.multi; j++) + { + plotter->Fill1D("PC_Time_qqq", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + plotter->Fill2D("PC_Time_Vs_QQQ_ch", 200, -2000, 2000, 16 * 8, 0, 16 * 8, anodeT - cathodeT, qqq.ch[j], "hTiming"); + plotter->Fill2D("PC_Time_vs_AIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, anodeIndex, "hTiming"); + plotter->Fill2D("PC_Time_vs_CIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, cathodeIndex, "hTiming"); + // plotter->Fill1D("PC_Time_A" + std::to_string(anodeIndex) + "_C" + std::to_string(cathodeIndex), 200, -1000, 1000, anodeT - cathodeT, "TimingPC"); + } + + for (int j = 0; j < sx3.multi; j++) + { + plotter->Fill1D("PC_Time_sx3", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + + plotter->Fill1D("PC_Time", 200, -2000, 2000, anodeT - cathodeT, "hTiming"); + } + + for (int j = i + 1; j < pc.multi; j++) + { + plotter->Fill2D("PC_Coincidence_Matrix", 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("PC_Coincidence_Matrix_anodeMinusCathode_lt_-200_" + std::to_string(anodeT - cathodeT < -200), 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC"); + plotter->Fill2D("Anode_V_Anode", 24, 0, 24, 24, 0, 24, pc.index[i], pc.index[j], "hGMPC"); + } + } + + anodeHits.clear(); + cathodeHits.clear(); + corrcatMax.clear(); + + int aID = 0; + int cID = 0; + double aE = 0; + double cE = 0; + double aESum = 0; + double cESum = 0; + double aEMax = 0; + int aIDMax = 0; + + for (int i = 0; i < pc.multi; i++) + { + // if (pc.e[i] > 100) + { + if (pc.index[i] < 24) + anodeHits.push_back(std::pair(pc.index[i], pc.e[i])); + else if (pc.index[i] >= 24) + cathodeHits.push_back(std::pair(pc.index[i] - 24, pc.e[i])); + } + } + + // std::sort(anodeHits.begin(), anodeHits.end(), [](const std::pair &a, const std::pair &b) + // { return a.second > b.second; }); + // std::sort(cathodeHits.begin(), cathodeHits.end(), [](const std::pair &a, const std::pair &b) + // { return a.second > b.second; }); + + if (anodeHits.size() >= 1 && cathodeHits.size() >= 1) + { + // 2. CRITICAL FIX: Define reference vector 'a' + // In Analyzer.cxx, 'a' was left over from the loop. We use the first anode wire as reference here. + // (Assuming pwinstance.An is populated and wires are generally parallel). + TVector3 refAnode = pwinstance.An[0].first - pwinstance.An[0].second; + + { + for (const auto &anode : anodeHits) + { + aID = anode.first; + aE = anode.second; + aESum += aE; + if (aE > aEMax) + { + aEMax = aE; + aIDMax = aID; + } + } + + for (const auto &cathode : cathodeHits) + { + cID = cathode.first; + cE = cathode.second; + plotter->Fill2D("AnodeMax_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aIDMax, cID, "hRawPC"); + plotter->Fill2D("Anode_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aID, cID, "hRawPC"); + plotter->Fill2D("Anode_vs_CathodeE", 2000, 0, 30000, 2000, 0, 30000, aE, cE, "hGMPC"); + plotter->Fill2D("CathodeMult_V_CathodeE", 6, 0, 6, 2000, 0, 30000, cathodeHits.size(), cE, "hGMPC"); + for (int j = -4; j < 3; j++) + { + if ((aIDMax + 24 + j) % 24 == 23 - cID) + { + corrcatMax.push_back(std::pair(cID, cE)); + cESum += cE; + } + } + } + } + } + + TVector3 anodeIntersection; + anodeIntersection.Clear(); + if (corrcatMax.size() > 0) + { + double x = 0, y = 0, z = 0; + for (const auto &corr : corrcatMax) + { + if (Crossover[aIDMax][corr.first][0].z > 9000000) + continue; + if (cESum > 0) + { + x += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].x; + y += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].y; + z += (corr.second) / cESum * Crossover[aIDMax][corr.first][0].z; + } + } + if (x == 0 && y == 0 && z == 0) + ; + // to ignore events with no valid crossover points + else + anodeIntersection = TVector3(x, -y, -z); + // std::cout << "Anode Intersection: " << anodeIntersection.X() << ", " << anodeIntersection.Y() << ", " << anodeIntersection.Z() << std::endl; + } + bool PCQQQPhiCut = false; + // flip the algorithm for cathode 1 multi anode events + if ((hitPos.Phi() > (anodeIntersection.Phi() - TMath::PiOver4())) && (hitPos.Phi() < (anodeIntersection.Phi() + TMath::PiOver4()))) { + PCQQQPhiCut = true; + } + + // for (double Tz = -190; Tz <= 190; Tz += 10.0) + // { + // TVector3 TargetPos(0, 0, Tz); + // plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut) + "_TZ" + std::to_string(Tz), 90, 0, 180, 120, 0, 180, (anodeIntersection - TargetPos).Theta() * 180. / TMath::Pi(), (hitPos - TargetPos).Theta() * 180. / TMath::Pi(), "TPosVariation"); + // } + + if (anodeIntersection.Z() != 0) + { + plotter->Fill1D("PC_Z_Projection", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("Z_Proj_VsDelTime", 600, -300, 300, 200, -2000, 2000, anodeIntersection.Z(), anodeT - cathodeT, "hPCzQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi", 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("Inttheta_vs_QQQtheta", 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut), 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ"); + plotter->Fill2D("IntPhi_vs_QQQphi_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() >= 2) + plotter->Fill1D("PC_Z_Projection_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 1) + { + plotter->Fill1D("PC_Z_proj_1C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_1C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill1D("PC_Z_proj_2C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_2C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeIntersection.Z() != 0 && cathodeHits.size() > 2) + { + plotter->Fill1D("PC_Z_proj_nC", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + plotter->Fill2D("IntersectionPhi_vs_AnodeZ_nC", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC"); + } + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + plotter->Fill2D("AHits_vs_CHits", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // make another plot with nearest neighbour constraint + bool hasNeighbourAnodes = false; + bool hasNeighbourCathodes = false; + + // 1. Check Anodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < anodeHits.size(); i++) + { + for (size_t j = i + 1; j < anodeHits.size(); j++) + { + int diff = std::abs(anodeHits[i].first - anodeHits[j].first); + if (diff == 1 || diff == 23) + { // 23 handles the cylindrical wrap + hasNeighbourAnodes = true; + break; + } + } + if (hasNeighbourAnodes) + break; + } + + // 2. Check Cathodes for neighbours (including wrap-around 0-23) + for (size_t i = 0; i < cathodeHits.size(); i++) + { + for (size_t j = i + 1; j < cathodeHits.size(); j++) + { + int diff = std::abs(cathodeHits[i].first - cathodeHits[j].first); + if (diff == 1 || diff == 23) + { + hasNeighbourCathodes = true; + break; + } + } + if (hasNeighbourCathodes) + break; + } + + // --------------------------------------------------------- + // FILL PLOTS + // --------------------------------------------------------- + if (anodeHits.size() > 0 && cathodeHits.size() > 0) + { + plotter->Fill2D("AHits_vs_CHits_NA" + std::to_string(hasNeighbourAnodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + plotter->Fill2D("AHits_vs_CHits_NC" + std::to_string(hasNeighbourCathodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + + // Constraint Plot: Only fill if BOTH planes have adjacent hits + // This effectively removes events with only isolated single-wire hits (noise) + if (hasNeighbourAnodes && hasNeighbourCathodes) + { + plotter->Fill2D("AHits_vs_CHits_NN", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC"); + } + } + + if (HitNonZero && anodeIntersection.Z() != 0) + { + pw_contr.CalTrack2(hitPos, anodeIntersection); + plotter->Fill1D("VertexRecon", 600, -1300, 1300, pw_contr.GetZ0()); + plotter->Fill1D("VertexRecon_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -300, 300, pw_contr.GetZ0()); + + if (cathodeHits.size() == 2) + plotter->Fill1D("VertexRecon_2c_TC"+std::to_string(PCQQQTimeCut)+"_PhiC"+std::to_string(PCQQQPhiCut), 600, -300, 300, pw_contr.GetZ0()); + } + + for (int i = 0; i < qqq.multi; i++) + { + if (PCQQQTimeCut) { + plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + } + plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ"); + + for (int j = i + 1; j < qqq.multi; j++) + { + if (qqq.id[i] == qqq.id[j]) + { + int chWedge = -1; + int chRing = -1; + double eWedge = 0.0; + double eWedgeMeV = 0.0; + double eRing = 0.0; + double eRingMeV = 0.0; + double tRing = 0.0; + int qqqID = -1; + if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]) + { + chWedge = qqq.ch[i]; + eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16]; + chRing = qqq.ch[j] - 16; + eRing = qqq.e[j]; + tRing = static_cast(qqq.t[j]); + qqqID = qqq.id[i]; + } + else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]) + { + chWedge = qqq.ch[j]; + eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16]; + chRing = qqq.ch[i] - 16; + tRing = static_cast(qqq.t[i]); + eRing = qqq.e[i]; + qqqID = qqq.id[i]; + } + else + continue; + + if (qqqCalibValid[qqq.id[i]][chRing][chWedge]) + { + eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + eRingMeV = eRing * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000; + } + else + continue; + + // if (anodeIntersection.Z() != 0) + { + plotter->Fill2D("PC_Z_vs_QQQRing", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2) + { + plotter->Fill2D("PC_Z_vs_QQQRing_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQRing_2C" + std::to_string(qqq.id[i]), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ"); + plotter->Fill2D("PC_Z_vs_QQQWedge_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chWedge, "hPCzQQQ"); + } + plotter->Fill2D("Vertex_V_QQQRingTC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, 16, 0, 16, pw_contr.GetZ0(), chRing, "hPCQQQ"); + double phi = TMath::ATan2(anodeIntersection.Y(), anodeIntersection.X()) * 180. / TMath::Pi(); + plotter->Fill2D("PolarAngle_Vs_QQQWedge" + std::to_string(qqqID), 360, -360, 360, 16, 0, 16, phi, chWedge, "hPCQQQ"); + // plotter->Fill2D("EdE_PC_vs_QQQ_timegate_ls1000"+std::to_string()) + + plotter->Fill2D("PC_Z_vs_QQQRing_Det" + std::to_string(qqqID), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCQQQ"); + //double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); + //double rho = 50. + 40. / 16. * (chRing + 0.5); + + for (int k = 0; k < pc.multi; k++) + { + if(pc.index[k] >= 24) + continue; + + double sinTheta = TMath::Sin(hitPos.Theta()); + + plotter->Fill2D("CalibratedQQQE_RvsPCE_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 1000, 0, 10, 2000, 0, 30000, eRingMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("CalibratedQQQE_WvsPCE_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 1000, 0, 10, 2000, 0, 30000, eWedgeMeV, pc.e[k]*sinTheta, "hPCQQQ"); + plotter->Fill2D("PCQQQ_dTimevsdPhi", 200, -2000, 2000, 80, -200, 200, tRing - static_cast(pc.t[k]), (hitPos.Phi()-anodeIntersection.Phi()) * 180. / TMath::Pi(), "hTiming"); + } + } + } + } + for (int i = 0; i < sx3.multi; i++) + { + // plotting sx3 strip hits vs anode phi + if (sx3.ch[i] < 8) + plotter->Fill2D("AnodePhi_vs_SX3Strip", 100, -200, 200, 8 * 24, 0, 8 * 24, anodeIntersection.Phi() * 180. / TMath::Pi(), sx3.id[i] * 8 + sx3.ch[i]); + } + + if (anodeIntersection.Z() != 0 && cathodeHits.size() == 3) + { + plotter->Fill1D("PC_Z_proj_3C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ"); + } + + plotter->Fill2D("AnodeMaxE_Vs_Cathode_Sum_Energy", 2000, 0, 30000, 2000, 0, 30000, aEMax, cESum, "hGMPC"); + plotter->Fill1D("Correlated_Cathode_MaxAnode", 6, 0, 5, corrcatMax.size(), "hGMPC"); + plotter->Fill2D("Correlated_Cathode_VS_MaxAnodeEnergy", 6, 0, 5, 2000, 0, 30000, corrcatMax.size(), aEMax, "hGMPC"); + plotter->Fill1D("AnodeHits", 12, 0, 11, anodeHits.size(), "hGMPC"); + plotter->Fill2D("AnodeMaxE_vs_AnodeHits", 12, 0, 11, 2000, 0, 30000, anodeHits.size(), aEMax, "hGMPC"); + + if (anodeHits.size() < 1) + { + plotter->Fill1D("NoAnodeHits_CathodeHits", 6, 0, 5, cathodeHits.size(), "hGMPC"); + } + + return kTRUE; +} + +void TrackRecon::Terminate() +{ + plotter->FlushToDisk(); +} diff --git a/anasen_analysis_vignesh/WedgeChVAnode.jpeg b/anasen_analysis_vignesh/WedgeChVAnode.jpeg new file mode 100644 index 0000000..81adcec Binary files /dev/null and b/anasen_analysis_vignesh/WedgeChVAnode.jpeg differ diff --git a/anasen_analysis_vignesh/buildEvents.sh b/anasen_analysis_vignesh/buildEvents.sh new file mode 100755 index 0000000..2e4a6a6 --- /dev/null +++ b/anasen_analysis_vignesh/buildEvents.sh @@ -0,0 +1,19 @@ +#!/bin/bash + +if [ "$#" -ne 2 ]; then + echo "Usage: $0 runID timeWindow_ns" + echo "Exiting..." + exit 1 +fi + +runID=$1 +timeWindow=$2 + +rawFolder=/media/nvmeData/ANASEN_test +rootFoler=/media/nvmeData/ANASEN_test/root_data + +fileList=`\ls -1 ${rawFolder}/*${runID}*.fsu` + +./EventBuilderNoTrace ${timeWindow} 0 ${fileList} + +mv -vf ${rawFolder}/*${runID}*${timeWindow}_noTrace.root ${rootFoler}/. \ No newline at end of file diff --git a/anasen_analysis_vignesh/elog/elogd.cfg b/anasen_analysis_vignesh/elog/elogd.cfg new file mode 100644 index 0000000..a0fc656 --- /dev/null +++ b/anasen_analysis_vignesh/elog/elogd.cfg @@ -0,0 +1,1109 @@ +[global] +port = 8080 +URL = https://fsunuc.physics.fsu.edu/elog/ +#URL = https://elog.physics.fsu.edu/ +SSL = 0 +Protect Selection page = 0 +Password file = /data0/elog/password.xml +Self register = 3 +logfile = /data0/elog/log.txt +SMTP host = mailrelay.fsu.edu +#Restrict edit time = 168 +#origin:/usr/local/elog/logbooks +logbook dir = /data0/elog/logbooks +Max content length = 204857600 + +Welcome Title =

Welcome to FSU Fox's Lab Elog + +Login expiration = 24 +Admin user = rtang, alconley, mspieker, Sudarsan + +Group FSU Experiments = ANASEN, CATRiNA, Clarion2, ENCORE, Gamma-Spectroscopy, Kemper, Laser-Spectroscopy, RESOLUT, RESONEUT, Split-Pole, CeBrA +Group FRIB Experiments = e21062_analysis, 2022_05_e21062_FRIB +Group Beams production = Maintenance, Beams production +Group Lab Maintenance = fsunuc, Pixie_NSCLDAQ, LabMaintenance, dataServer, SOLARIS-DAQ, tandem_dashboard, test2 + + +Group ANASEN = ANASEN_test, ANASEN_test_PC, 202404_24Mg_a_p, 202406_27Al, 202409_17F_ap +Group CATRiNA = 2024_08_19_7Li_3He_n, 2025_05_11B_11B +Group Clarion2 = 20220110_example, 202203_64Ni_7Li, 202411_11B_70Zn +Group ENCORE = 2023_08_Encore, 2025_04_17O_a_n, 2025_10_44Ti_irradiation +Group Gamma-Spectroscopy = testClover +Group Kemper = FSUDAQ_testing +Group Laser-Spectroscopy = EMPTY +Group RESOLUT = 2025_11_7Be_dn_8B +Group RESONEUT = 2022_12Cdn13N, MESYTEC_digitizer, 2022_08_19Ne_dn, 2023_10_17F_pa +Group Split-Pole = 2022_04_SPS_Blocker, 2022_05-06_3He_2H, 2022_05_mirror_transfer, 2022_06_11B_alpha_transfer, 2022_07_REU_dp, 2022_09_10_CeBrA, 2023_01_30_6Li, 2023_02_07_19F_dp, 2023_03_06_32S_6Li_t, 2023_12_12C_6He_LSU, 2024_02_49Ti_d_3He, 2024_07_36S_dp_RU, 2024_07_24Mg_28Si_3He_t, 2024_08_12C_dp_FSUtesting, 2025_02_ICESPICE_Demonstrator, 2025_02_SABRE, 2025_03_SPS_SABRE_58Ni_3He_t, 2025_06_13C_Campaign, 2025_07_29Si_dp, 2025_08_7Li, 2025_10_TritumCommissioning +Group CeBrA = 2023_07_REU, 2023_7_144Sm_6Li_dg, 2024_07_61Ni_dp_RU, 2025_04_180Hf_dpg, 2025_06_150Nd_ptg + +[fsunuc] +Theme = default +Comment = fsunuc.physics.fsu.edu: software installation and configuration +Page Title = ELOG - 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$Subject +Reverse sort = 1 +Quick filter = Date +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other +Extendable Options = Category +Attributes = Author, Email, Revised, Category, Subject +Locked Attributes = Author, Email, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject + +[Pixie_NSCLDAQ] +Theme = default +Comment = NSCL DAQ setup and config +Page Title = ELOG - $Subject +Reverse sort = 1 +Quick filter = Date, Category, Type +Options Category = Software, Network, Other, Hardware, Hardware/Software +Options Type = PIXIE-16, VME, GAM_computer, evt, ROOT +Extendable Options = Category, Type +Attributes = Author, Email, Revised, Category, Type, Subject +Locked Attributes = Author, Email, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject +List display = ID, Date, Author, Category, Subject + +[2023_08_Encore] +Theme = default +Comment = Test, should be renamed. +Page Title = ELOG - $Subject +Reverse sort = 1 +Quick filter = Date, Type +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other, Run +Extendable Options = Category +Attributes = Author, Email, Revised, Category, Subject +Locked Attributes = Author, Email, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject + +[LabMaintenance] +Theme = default +Comment = Lab Maintenance +Page Title = ELOG - $Subject +Reverse sort = 1 +Quick filter = Date +Options Category = Hardware, Software, Network, Other +Extendable Options = Category +Attributes = Author, Email, Revised, Category, Subject +Locked Attributes = Author, Email, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject +List display = ID, Date, Author, Category, Subject + +[MESYTEC_digitizer] +Theme = default +Comment = NSCL DAQ setup and config +Page Title = ELOG - 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$Subject +Reverse sort = 1 +Quick filter = Date, Category +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other, Run, Procedure, Junk, Calibration +Extendable Options = Category +Attributes = Author, Revised, Category, Subject, Reaction, RunNo +Locked Attributes = Author, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject +Entries per page = 100 +All display limit = 1000 + +[2025_05_11B_11B] +Admin user = admin, rtang, alconley +Theme = default +Comment = +Page Title = ELOG - $Subject +Reverse sort = 1 +Quick filter = Date, Category +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other, Run, Procedure, Junk, Calibration +Extendable Options = Category +Attributes = Author, Revised, Category, Subject, Reaction, RunNo +Locked Attributes = Author, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject +Entries per page = 100 +All display limit = 1000 + +[2025_06_150Nd_ptg] +Admin user = admin, rtang, alconley, Sudarsan +Theme = default +Comment = +Page Title = ELOG - $Subject +Reverse sort = 1 +Quick filter = Date, Category +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other, Run, Procedure, Junk, Calibration +Extendable Options = Category +Attributes = Author, Revised, Category, Subject, Reaction, Angle, Field, BCI Scale, RunNo +Locked Attributes = Author, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject +Entries per page = 100 +All display limit = 1000 + +[2025_06_13C_Campaign] +Admin user = admin, rtang, alconley +Theme = default +Comment = +Page Title = ELOG - $Subject +Reverse sort = 1 +Quick filter = Date, Category +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other, Run, Procedure, Junk +Extendable Options = Category +Attributes = Author, Revised, Category, Subject, Reaction, Angle, Field, BCI Scale, RunNo +Locked Attributes = Author, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject +Entries per page = 100 +All display limit = 1000 + +[2025_07_29Si_dp] +Admin user = admin, rtang, alconley +Theme = default +Comment = +Page Title = ELOG - 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$Subject +Reverse sort = 1 +Quick filter = Date, Category +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other, Run, Procedure, Junk, Calibration +Extendable Options = Category +Attributes = Author, Revised, Category, Subject, Reaction, RunNo +Locked Attributes = Author, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject +Entries per page = 100 +All display limit = 1000 + +[2025_11_7Be_dn_8B] +Theme = default +Comment = Rajat's 7Be(d,n)8B Experiment +Page Title = ELOG - $Subject +Reverse sort = 1 +Quick filter = Date +Options Category = Preparation, Hardware, Software, General, Online Analysis, Other, Run, Instructions +Extendable Options = Category +Attributes = Author, Revised, Category, Subject, Reaction, BCI Scale, RunNo +Locked Attributes = Author, Email, Revised +Required Attributes = Subject +Preset Author = $long_name from $remote_host +Preset Email = $user_email +Preset Revised = $date +Subst on edit Revised = $date +Preset on reply Subject = Re:$Subject + diff --git a/anasen_analysis_vignesh/eloss_calculations/make_eloss_table.C b/anasen_analysis_vignesh/eloss_calculations/make_eloss_table.C new file mode 100644 index 0000000..0bdea7a --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/make_eloss_table.C @@ -0,0 +1,13 @@ +#include "/home/sud/Desktop/Software2/propagator/elastcaller.h" +void make_eloss_table() { + double einput = 6.0, estepnow; + double target_thickness_unit = 1e-3; //mg/cm2. + double density = 0.0711;//mg/cm3 + long i=0; + while(einput > 4.0) { + std::cout << "After " << i << " steps, 4He is at " << einput << " MeV after penetrating " << i*target_thickness_unit << " mg/cm2 " << i*target_thickness_unit/density << " cm of HeCO2" << std::endl; + estepnow = slowmedown("4He",einput,"3(12C)6(16O)97(4He)",target_thickness_unit); + einput = estepnow; + i+=1; + } +} diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/a.out b/anasen_analysis_vignesh/eloss_calculations/stopit/a.out new file mode 100755 index 0000000..12fac14 Binary files /dev/null and b/anasen_analysis_vignesh/eloss_calculations/stopit/a.out differ diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/desorb.for b/anasen_analysis_vignesh/eloss_calculations/stopit/desorb.for new file mode 100755 index 0000000..65c6a83 --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/desorb.for @@ -0,0 +1,811 @@ + subroutine desorb(ianz,zp,ap,ep,loste) + +C ** CALCULATES ENERGY LOSS IN AN ABSORBER SANDWICH ******* +C **** ENERGY DEPOSIT IN SECTIONS OF IONIZATION ********** +C *************** CHAMBER (DE1, DE2, AND DE3) ************ + + + PARAMETER (DSEP0=4.0,isold0=1) + + COMMON ISG(19),INN(19),DEN(19),THK(19),PRS(19),XLN(19),ARDEN(19) + 1 ,ZNUMB(19,4),ANUMB(19,4),ELNUM(19,4),CONCN(19,4) + 1 ,PRDEN(19,4),PRTHK(19,4) + DIMENSION ZNUMBW(4),ANUMBW(4),ELNUMW(4),CONCNW(4) + 1 ,PRDENW(4),PRTHKW(4) + DIMENSION E(19),DE(19),xmem(19) + DIMENSION TOUT(19),TOUTE(19) + dimension eptable(50,500,2),emintabz(50),ianzv(5) + real loste(19) + DATA io1,IO2,IO3,io0/9,11,12,1/ + data iopt,ianzi,ianzide/1,2,1/ +c + save eltimo,izmax,izth + +c the mass table is to be used only for iopt = 5,6 +c use atomic masses to average for isotipic composition. +c taken from Formulas Facts and Constants, H. J. Fischbeck and +c K. H. Fischbeck. Springer - Verlag 1987 2nd ed, pages 164-183. + + dimension amass(70) + data amass/1.01,4.00,6.94,9.01,10.81,12.01,14.01,16.00,19.00 + 1,20.18,22.99,24.31,26.98,28.09,30.97,32.07,35.45,39.95 + 2,39.10,40.08,44.96,47.88,50.94,52.00,54.94,55.85,58.93 + 3,58.69,63.55,65.39,69.72,72.59,74.92,78.96,79.90,83.80 + 4,85.47,87.62,88.91,91.22,92.91,95.94,98.,101.07,102.91 + 5,106.42,107.87,112.41,114.82,118.71,121.75,127.60,126.90 + 6,131.29,132.91,137.33,138.91,140.12,140.91,144.24,147. + 7,150.36,151.96,157.25,158.93,162.5,164.93,167.26,168.93 + 8,173.04/ + +c for Z > 70, you are in trouble !! +c +c open(unit=IO1, status='OLD', file='absorb.inp') + open(unit=IO2, status='OLD', file='desorb.out') +c rewind IO1 +c rewind IO2 +c +10 CONTINUE + + +C IOPT = 1 - SUPPLY ENERGY OF PARTICLE ENTERING +C THE ABSORBER ARRAY AND GET LOSS AND +C RANGES +C IOPT = 2 - SUPPLY TARGET, PROECTILE AND EJECTILE +C INFO. AND THEN GO THROUGH ABSORBER +C SANDWICH +C IOPT = 3 - CALCULATE ENERGY DEPOSITS IN DETECTOR +C DETECTOR DIMENSIONS ARE STANDARD AND +C THE VARIABLE -'IDET' - CHOOSES BETWEEN +C VARIETY OF AVAILABLE DETECTORS +C IOPT = 4 - FINDS MAXIMUM ENERGY THAT CAN BE STOPPED IN +C IANZ ELEMENTS OF THE SANDWICH FOR GIVEN +C ZP, AP. +C WHEN CALCULATION IS FINISHED, THE PROGRAM READS +C IN NEW VALUES OF ZP, AP AND RESTARTS. TO END +C THE PROGRAM, GIVE ZP < 0. +C IN ORDER TO HELP THE SPEED OF THE PROGRAM, +C GIVE THE PARTICLE'S "Z" IN increasing ORDER. +C IOPT = 5 - STORES ARRAYS OF Edet AS A FUNCTION OF INCIDENT +C ENERGY AND THE PARTICLE'S ID (Z,A) +C ARRAY LABELED eptable(Z-Zth,Einc,ipunch) +C ipunch = 1 stopped, = 2 punched through +c Einc = E(incident)/detable +C Zth = lowest Z considered - 1 +C +C ************************************************************ + +c read(io1,*) iopt +c1 FORMAT(10I) + DSEP = DSEP0 + isold = isold0 +c + IF(iopt.LT.0) GO TO 2000 + + +C *********************************************************** +c + if(iopt.eq.3) then + open(unit=IO3, status='OLD', file='absorbv.out') + rewind IO3 + endif +c + if(iopt.ge.5) then + do itpun = 1,2 + do itblz = 1,50 + emintabz(itblz) = 0. + do itble = 1,500 + eptable ( itblz,itble,itpun ) = 0. + enddo + enddo + enddo +c + open(unit=io0, status='UNKNOWN', file='abs.tbl') + rewind io0 +c + else + endif + +C *********************************************************** + +c ianz = number of elements in absorber "sandwich" - the +c particle deposits all its energy in these layers. +c ianzi = index of last layer in which the energy of the +c particle is not recorded - this unreecorded energy +c is used in the DST production in two modes: +c when making DST tape from data: +c Since the detector records only deposited energy +c the output tables are used to correct for this +c deficinecy and for a given dharge and mass extrapolate +c the measured energy to the target exit energy +c when making DST tape from model calculations: +c The "lost" energy is a source of broadening of the +c energy spectra due to straggling - this "smearing" +c is estimated and superposed on the calculated spectra. +c ianzide = element # for DE calculation +c +c read(IO1,*) ianz,ianzi,ianzide +c +c ianzv(5) +c = Index of layer where exiting particle velocit is +c calculated (only for option 3) max = 5 +c +c if(iopt.eq.3) read (IO1,*) knz +c if(iopt.eq.3) read (IO1,*) (ianzv(k),k=1,knz) +C *********************************************************** + +C AP = PROJECTILE MASS +C ZP = PROJECTILE CHARGE +C EP = PROJECTILE ENERGY +c +c read(io1,*) zp,ap,ep +2 FORMAT(f10.3) + +C ************************************************************* +c +c zth= threshold Z for incident energy tble calc. (iopt=5,6) +c zmax = maximum z for table calculation +c detable = the energy step size used for array storage +c emin = starting incident energy for table +c emax = mazximum incident energy for table calculation +c EP is ignored when iopt = 5 or 6 +c + if(iopt.ge.5) then + read(IO1,*) zth,zmax,emintab,emaxtab,detable + eltimeo = secnds(0.0) ! start timing + izth = ifix (zth + 0.01) + izmax = ifix (zmax + 0.01) +c +c if detable > emintab change emintab to 1/2 * detable +c + if(emintab.lt.detable) emintab = 0.5*detable + write(io2,291) zth+1,zmax,emintab,emaxtab,detable + else + endif +c +C ************************************************************ + +C IN THE FOLLOWING THE LISTED VARIABLES ARE INDEXED +C THE INDICES I AND J STAND FOR THE FOLLOWING: +C - I - SERIAL NUMBER OF ABSORBER LAYER (<20) +C - J - SERIAL NUMBER OF ELEMENT WITHIN LAYER (<5) + +C ************************************************************* + + +C ISG(I) = 0 - FOR SOLID ABSORBERS +C (I) = 1 - FOR GASEOUS ABSORBERS +C INN(I) = NUMBER OF ELEMENTS IN ONE LAYER +C (E.G. CH4 HAS TWO ELEMENTS C AND H) +C DEN(I) = DENSITY OF ABSORBE (FOR SOLIDS) +C THK(I) = THICKNESS OF ABSORBER IN MG/CMSQ (FOR SOLIDS) +C PRS(I) = PRESSURE (IN MM HG) FOR GAS ABSORBER +C XLN(I) = PHYSICAL LENGTH OF ABSORBER ( IN CM ) FOR GAS + +C **** ABSORBER COMPOSITION **** + +C ELNUM(I,J) = NUMBER OF ATOMS OF ELEMENT J IN LAYER I +C CONCN(I,J) = CONCENTRATION (MOLAR) OF ELEMENT J IN LAYER I +C ANUMB(I,J) = MASS NUMBER OF ELEMENT J IN LAYER I +C ZNUMB(I,J) = ATOMIC NUMBER OF ELEMENT J IN LAYER I + +C PRDEN(I,J) = PARTIAL DENSITY OF ELEMENT J IN LAYER I +C PRTHK(I,J) = PARTIAL THICKNESS OF ELEMENT J IN LAYER I (MG/CMSQ) + +C MAXIMUM OF NINETEEN LAYERS SPECIFIED + + +C ************************************************************* + + DO 100 ISN=1,IANZ +c read(io1,*) ISG(ISN),INN(ISN) + IF(ISG(ISN).EQ.1) GO TO 50 +c read(io1,*) DEN(ISN),THK(ISN) + TOUT(ISN)=THK(ISN)/(DEN(ISN)*1000.) + TOUTE(ISN)=TOUT(ISN)/2.54 + DO 20 IMN=1,INN(ISN) +c read(io1,*) ANUMB(ISN,IMN),ZNUMB(ISN,IMN), +c 1 ELNUM(ISN,IMN),CONCN(ISN,IMN) +20 CONTINUE + GO TO 100 +50 continue +c read(io1,*) PRS(ISN),XLN(ISN) + DO 60 IMN=1,INN(ISN) +c read(io1,2) ANUMB(ISN,IMN),ZNUMB(ISN,IMN), +c 1 ELNUM(ISN,IMN),CONCN(ISN,IMN) +60 CONTINUE +100 CONTINUE + +C **************************************************************** + + if(iopt.ne.5.and.iopt.ne.6) WRITE(IO2,101) ap,zp,ep + if(iopt.ne.5.and.iopt.ne.6) WRITE(IO2,102) ianz + +C ***************************************************************** + + DO 200 I=1,ianz + INNW=INN(I) + DO 210 J=1,INNW + ANUMBW(J)=ANUMB(I,J) + ZNUMBW(J)=ZNUMB(I,J) + ELNUMW(J)=ELNUM(I,J) + CONCNW(J)=CONCN(I,J) +210 CONTINUE + DENW=DEN(I) + XLNW=XLN(I) + PRSW=PRS(I) + THKW=THK(I) + IF(ISG(I).EQ.1) GO TO 250 + CALL SETABS(INNW,ANUMBW,ZNUMBW,ELNUMW,PRTHKW,THKW,PRDENW,DENW) + DO 230 J=1,INNW + PRDEN(I,J)=PRDENW(J) + PRTHK(I,J)=PRTHKW(J) +230 CONTINUE + GO TO 200 + +250 CALL SETABG(INNW,ANUMBW,ZNUMBW,ELNUMW,CONCNW,PRTHKW,THKW + 1, PRDENW,DENW,PRSW,XLNW) + DEN(I)=0. + THK(I)=0. + DO 270 J=1,INNW + PRDEN(I,J)=PRDENW(J) + PRTHK(I,J)=PRTHKW(J) + DEN(I)=DEN(I)+PRDEN(I,J) + THK(I)=THK(I)+PRTHK(I,J) +270 CONTINUE +200 CONTINUE + +C ************************************************************* + +C START CALCULATION AND DETAILED PRINTOUT + +C ************************************************************* +c + if(iopt.ge.5) then + ep = emintab + zp = zth + 1. + indexz = ifix (zp - zth + 0.001) + endif +c +299 continue ! come here for new particle (zp change) + + izp = ifix (zp+0.001) +c + if(iopt.ge.5) then + if (izp.gt.70) then + write (6,*) 'no mass for Z = ',izp + stop + else + ap = amass(izp) + +c The trick!. To calculate energy losses for deuterons and tritons, +c enter zth = 0.2 and 0.3 respectively. E. Chavez jul/92 + + if (izp.eq.1) then + iap = ifix (zth*10.0 + 0.1) + ap = float (iap) + end if + end if + end if +c + if (iopt.eq.6) then + ideltalay = 8 ! choose DE3 for eloss signal + if(izp.eq.1) ideltalay = 16 ! choose DEh for eloss signal + endif +c +300 CONTINUE ! come here for new energy (ep) +c + EI=ep + XUPDN=-1. + EPS=0.0001 + I1STPASS = 1 + + IF (iopt.EQ.4) GO TO 600 + + ipunch = 2 + DO 510 I=1,IANZ ! begin loop over absorber layers +c + if(iopt.ge.5) go to 504 + IF(ISG(I).EQ.0) WRITE(IO2,311) I,THK(I),TOUT(I),TOUTE(I),DEN(I) + IF(ISG(I).EQ.1) WRITE(IO2,312) I,THK(I),PRS(I),XLN(I),DEN(I) + DO 320 J=1,INN(I) + WRITE(IO2,321) ANUMB(I,J),ZNUMB(I,J),PRTHK(I,J) +320 CONTINUE +504 continue +c +c XNS - initial no. of intervals for integration of DE + XNS = 2. +c EI = energy in + CALL ADS(I,XUPDN,XNS,EPS,ap,zp,EI,DEI,ISTAT) +c DEI = energy out - energy in ( < 0. for energy loss) + EIOLD=EI +c E(I) = energy left after I'th element (EP-DE(1)-DE(2)+...) +c if particle stopped in detector this is equal to energy lost +c in remaining layers + DE(I) = DEI + E(I) = EI + DEI + EI = E(I) + INS=IFIX(XNS+0.001) +c + if (iopt.ge.5) go to 505 + WRITE(IO2,401) INS,EIOLD,EI + loste(i)=-1.*de(i) + if (EI.LT.EPS.OR.ISTAT.EQ.-1) WRITE(IO2,402) I +505 continue + loste(ianz + 1)=e(ianz) +c +c if particle stopped in layer beyond ianzi we must +c check if iopt=5 or6 and calculate the energy loss in the +c front part (layers 1 thru ianzi). +c + istore = I + if (EI.lt.EPS) ipunch=1 +c control loop exit +c exit when particle runs out of energy in last layer + if (EI.LT.EPS.OR.ISTAT.EQ.-1) go to 701 +c if interested in DE signal only (iopt=6) exit after +c layer for which DE is sought was traversed + if(iopt.eq.6.and.I.ge.ianzide) go to 701 +c +510 CONTINUE ! end loop over absorber layers + +c this part for iopt=5,6 stores incident energy values + +701 continue + if(iopt.ne.5.and.iopt.ne.6) go to 520 +c +c establish higher energy cutoof for next step with higher z +c should save time in calulating energies of particles stopped +c in the dead layer + if( I.le.ianzi) emintabz(izp)=ep +c +c evalue = energy of particle when entering sensitive volume of det. +c when particle is stopped (ipunch=1) this is what is left +c once you take off the energy lost in the dead layer. + evalue = E(ianzi) +c = when particle punches thouough detector its energy at the +c end is EI - subtract this from what it entered with (after +c dead layers) and again you got the energy deposited. + if(ipunch.eq.2) evalue = E(ianzi) - EI +c roundoff errors could resutl in negative energies !! + if (evalue.lt.0.0) evalue = 0.0 + +c EI is current energy after last layer - is nonzero when particle +c punched through and to get energy deposited must subtract this +c "left over" energy from the energy of particle had when it entered +c the detector's sensitive volume + indexe = ifix((ep + 0.001)/detable) + 1 + indexz = ifix(zp - zth + 0.001) + if(iopt.eq.5) eptable(indexz,indexe,ipunch) = evalue + if(iopt.eq.6) ipunch = 1 + if(iopt.eq.6) eptable(indexz,indexe,ipunch) = -DE(ianzide) + +c now repeat calculation for same Z but new energy + ep = ep + detable + if(ep.gt.emaxtab) go to 709 + go to 300 + +709 continue +c reset energy to emintab and up zp by one until we top +c zmax - this portion controls looping over Z! + + do ieps = 1,ianz + E(ieps) = 0. + DE(ieps) = 0. + enddo + + ep = emintabz(izp) + zp = zp + 1. + izp = ifix(zp + 0.001) + emintabz(izp) = emintabz(izp-1) + + eltime = secnds (eltimeo) + itminutes = ifix(eltime/60.) + tminutes = float(itminutes) + tseconds = eltime - tminutes*60. + eltimeo = eltimeo + eltime + zpm1 = zp - 1. + if((izp-1).le.izmax) write(io2,714) zpm1,ap,tminutes,tseconds + 714 format(' finished Z=',f3.0,' A=',f4.0,' - ',f5.0, + +' minutes and ',f3.0,' seconds elapsed') + + if (izp.ge.izmax) go to 711 + go to 299 + +711 continue + +c get here when iopt = 5 or 6 calculation is done +c now ready to store array on disk + write(io0,712) zth,zmax,emintab,emaxtab,detable + + iemintab = ifix( (emintab + 0.001)/detable ) + 1 + iemaxtab = ifix( (emaxtab + 0.001)/detable ) + iztop = ifix(zp - 1. - zth + 0.001) + + do ipp = 1,2 + do indexz = 1, iztop + iztab = indexz + ifix(zth+0.01) + imasstab = ifix(amass(iztab) + 0.1) + if(iztop.eq.1) imasstab = ifix(ap + 0.1) + write(io0,7712) indexz,iztab,imasstab,iemintab,iemaxtab +7712 format(5i20) + itblow = iemintab + do indexe = iemintab,iemaxtab,10 + itbup = itblow + 9 + write(io0,713) (eptable(indexz,itbe,ipp),itbe=itblow,itbup) + itblow = itbup + 1 + enddo + enddo + enddo +712 format(5e16.8) +713 format(10e16.8) +c + close (unit = io0) +c +C MORE INPUT FOR NEW CALCULATION WITH SAME ABSORBERS + +520 CONTINUE + + +c read(io1,*) zp,ap,ep + zp = -1. + IF(zp.le.0.) GO TO 2000 + izp = ifix(zp + 0.001) + if(ap.le.0.) AP = amass(izp) + IF(zp.gt.0.) WRITE(IO2,101) ap,zp,ep + GO TO 299 + +600 DO I = 1, ianz + ILAY = I + XNS = 2.0 + CALL ADS(I,XUPDN,XNS,EPS,ap,zp,EI,DEI,ISTAT) + EIOLD = EI + DE(I) = DEI + E(I) = EI + DEI +c E(I) = energy left after I'th element (EP+DE(1)+DE(2)+...) +c if particle stopped in detector this is equal to energy lost +c in remaining layers + xmem(i) = E(I) + EI = E(I) + INS = IFIX(XNS + 0.001) +c WRITE (IO2,613) ILAY,INS,EI,ISTAT + IF (EI.LE.0.0.OR.ISTAT.EQ.-1) GO TO 601 + END DO + + +601 IF (ISTAT.EQ.0)THEN + IF (EI.LT.0.003.AND.EI.GE.0.0) THEN + WRITE(IO2,611) ap,zp,ep,ILAY,xmem(5),xmem(6),xmem(7) + read(io1,*) zp,ap + izp = ifix (zp + 0.001) + if(ap.le.0.) ap = amass(izp) + IF (zp.LT.0.0) GO TO 2000 + IPASS = 0 + I1STPASS = 1 + EI = ep + GO TO 600 + END IF + isign = isold + isold = 1 + ELSE + isign = - isold + isold = -1 + END IF + + IF (I1STPASS.gt.0) THEN + isign = 1 + I1STPASS = 0 + IF (ISTAT.EQ.0) THEN + DSEP = - DSEP0 + ELSE + DSEP = DSEP0 + END IF + END IF + +C IF THE INITIAL ENERGY WAS TOO LARGE, THEN THE ION WILL PUNCH THROUGH +C THE DETECTOR A NUMBER OF TIMES UNTIL THE ENERGY IS REDUCED BELOW +C THE PUNCH-THROUGH ENERGY (PTE). IF THE INITIAL ENERGY WAS TOO SHORT +C THEN IT WON'T UNTIL PTE IS REACHED. IN THIS MOMENT, IPASS IS SET TO +C ONE, AND FROM THIS POINT EVERY FURTHER CALCULATION WILL IMPLY A +C REDUCTION BY HALF OF THE SIZE OF "DSEP", AND A CHANGE OF SIGN ONLY +C IF APROPRIATE. + + IF (isign.LT.0) IPASS = 1 !IPASS=1 UNTIL "PTE" IS FOUND. + IF (IPASS.EQ.1) DSEP = isign * DSEP * 0.5 + + IF (ABS(DSEP).LT.0.05) THEN + EI = 0.00001 + ISTAT = 0 + GO TO 601 + END IF + + EP = EP + DSEP + ei = ep + + GO TO 600 + +1000 CONTINUE + GO TO 10 +2000 CONTINUE + +101 FORMAT(//////' PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER', + 1 ' SANDWICH '////' AP = ',F6.0,' ZP = ',F5.0, + 1 ' INITIAL ENERGY = ',F12.5//) +102 FORMAT(' ABSORBER SANDWICH CONTAINS - ',I2,' LAYERS'//) +291 format(' start absorber calculations for z =',f3.0 + +,' to z =',f3.0,/' and energies from emin =',f6.2 + +,' to emax =',f7.2,' in ',f6.2,'MeV steps') +311 FORMAT(//' LAYER # ',I2,' - SOLID ABSORBER - ', + 1' AREAL DENSITY = ',E10.4/' THICKNESS = ',E10.4, + 1' CM OR ',E10.4,' INCH DENSITY =',E10.3,' G/CM3') +312 FORMAT(//' LAYER # ',I2,' - GAS ABSORBER - ', + 1' AREAL DENSITY = ',E10.4/' PRESSURE = ',E10.4, + 1' TORR LENGTH ',E9.4,'CM DENSITY =',E9.3,'MG/CM3') +321 FORMAT(7X,' A =',F6.0,' Z =',F5.0,' AREAL DENSITY' + 1,' (PARTIAL) = ',E12.5,' MG/CMSQ') +401 FORMAT(' CALC IN-',I4,' STEPS' + 1,' ENERGY IN = ',F8.3,' ENERGY OUT = ',F8.3 + 2,'(MEV)') +402 FORMAT(' CHARGED PARTICLE STOPPED IN LAYER # ',I2) +613 FORMAT (2X,'LAYER= ',I2,': ',I6,' ITERATIONS' + 1, ', E final= ',F10.4,' STATUS= ',I2) +611 FORMAT (2X,'Ion (A , Z): (',F4.0,' , ',F3.0 + 1,'), E(MeV)= ',F7.2,' STOPPED IN LAYER ',I2/ + 1' Esum = ',f7.2,' Esum-E1 = ',f7.2, + 1' Esum-E1-E2 = ',f7.2) +703 format(' eptable (',i2,', ',i3,', ',i1,' ) =',f8.2) + + return + END + + SUBROUTINE ADS(I1,SIGN,XN1,EPS,A,Z,E,DEE,ISTAT) + +C SUBROUTINE FOR ENERGY LOSS CALCULATIONS +C CALL DEDX FRO STOPPING POWER CALCULATIONS + + COMMON ISG(19),INN(19) + 1 ,DEN(19),THK(19),PRS(19),XLN(19),ARDEN(19) + 1 ,ZNUMB(19,4),ANUMB(19,4),ELNUM(19,4),CONCN(19,4) + 1 ,PRDEN(19,4),PRTHK(19,4) + +C N1= NUMBER OF SUBDIVISIONS FOR INTEGRATION +C OF ENERGY LOSS + +1000 CONTINUE + EH = E + N1 = IFIX(XN1+0.001) + DEDNEXT = 0. + DO 1010 K=1,N1 + J1 = INN(I1) + ISGW = ISG(I1) + I = I1 + DO 1001 J = 1,J1 + AX = ANUMB(I,J) + ZX = ZNUMB(I,J) + FX = PRTHK(I,J)/XN1 + DENST = PRDEN(I,J) + VH = VEL(EH,A) + CALL DEDX(Z,A,ZX,AX,DENST,EH,VH,ISGW,DEX,DE) + EH = EH + DE*SIGN*FX + IF(EH.LE.0.) THEN + IF (K.LE.2) THEN + N1 = N1 * 2 + XN1 = FLOAT(N1) + GO TO 1000 + END IF + ISTAT = -1 + GO TO 9910 + END IF + IF (K.LE.2) DEDNEXT = DEDNEXT + DE * FX +1001 CONTINUE + IF (K.EQ.1) THEN + DED1ST = DEDNEXT + DEDNEXT = 0.0 + END IF + IF (K.EQ.2) THEN + DDD = DED1ST - DEDNEXT + IF(DDD.LT.0.) DDD=-DDD + DDS = DED1ST + DEDNEXT + DDR = DDD/DDS + IF(DDR.GT.EPS) THEN + N1 = N1 * 2 + XN1 = FLOAT(N1) + GO TO 1000 + END IF + END IF +1010 CONTINUE + + ISTAT = 0 +9910 DEE = EH-E + + RETURN + END + + SUBROUTINE SETABS(INW,A,Z,AN,T,TH,D,DN) + +C SUBROUTINE FOR SETTING UP COMPOSITE ABSORBER +C DATA (PARTIAL DENSITIES AND THICKNESSES) + + DIMENSION A(4),Z(4),AN(4),T(4),D(4) + + AW=0. + DO 1 I=1,INW + AW=AW+A(I)*AN(I) +1 CONTINUE + DO 2 I=1,INW + AN(I)=A(I)*AN(I)/AW + T(I) = TH*AN(I) + D(I) = DN*AN(I) +2 CONTINUE + + RETURN + END + + SUBROUTINE SETABG(INW,A,Z,AN,CN,T,TH,D,DN,PR,XL) + +C SUBROUTINE FOR SETTING UP COMPOSITE ABSORBER DATA +C FOR GASEOUS LAYERS. + + DIMENSION A(4),Z(4),AN(4),CN(4),T(4),D(4) + + + P = PR/760. + X = XL/22.4 + + AWW=0. + AW=0. + DO 1 I=1,INW + AW = AW +A(I)*AN(I) + AWW= AWW+A(I)*AN(I)*CN(I) + T(I) = P*X*A(I)*AN(I)*CN(I) + D(I) = T(I)/XL +1 CONTINUE + RETURN + END + + FUNCTION VEL(ENER,A1) + + VV=SQRT(2.13E-3*ENER/A1) + VEL=VV + RETURN + END + + FUNCTION FKINEM(EP,AP,AT,TH) + + IF(AP.GT.AT) GOTO 100 + E=EP*AP**2/(AP+AT)**2 + E=E*(COS(TH)+SQRT((AT/AP)**2-SIN(TH)**2))**2 + FKINEM=E + RETURN +100 FKINEM=0. + RETURN + END + + FUNCTION FFKIN(EP,AP,AT,TH,Q) + +C INELASTIC SCATTERING + B=AP**2*EP/(AP+AT)**2/(EP+Q) + D=AT**2/(AP+AT)**2*(1.+AP*Q/AT/(EP+Q)) + E=(EP+Q)*B*(COS(TH)+SQRT(D/B-SIN(TH)**2))**2 + FFKIN=E + RETURN + END + + SUBROUTINE DEDX(Z1,A1,Z2,A2,RHO,ENER,V,IFG,DEDXHI,DEDXTO) + +C PROGRAM CALCULATES THE DIFFERENTIAL ENERGY LOSS DE/DX IN SOLID +C TARGETS USING A SEMIEMPIRICAL FORMULA DEDUCED FROM EXPERIMENTAL +C THE PROGRAM IS MODIFIED FOR GAS ABSORBERS. + +C REF.: K.BRAUNE,R.NOVOTNY,D.PELTE,D.HUSAR,D.SCHWALM, +C PROCEEDINGS - SPRING MEETING OF THE GERMAN PHYSICAL +C SOCIETY, VERHANDLUNGEN 4/1978 + +C K.BRAUNE, DIPLOM, HEIDELBERG 1979 + + +C H(Z2) IS A SUM OF FIVE GAUSSIAN FUNCTIONS. +C A1 MASS NUMBER - PROJECTILE +C Z2 ATOMIC NUMBER ABSORBER +C A1 MASS NUMBER ABSORBER +C RHO DENSITY OF THE ABSORBER (GRAMM/CM**3) +C (MEANLESS IF GAS ABSORBER ) +C ENER ENERGY OF THE PROJECTILE (MEV) +C V VELOCITY OF THE PROJECTILE +C IN MEV/(MG/CM**2) +C Z1 ATOMIC NUMBER - PROJECTILE + + IF(IFG.EQ.1) RHO=1. + XI=V**2/Z2 +C +C ABSORBER - FUNCTION +C G(XI)=Y(EXP)-Y(THEORY) - IS DEDUCED FROM EXPERIMENTAL ENERGY LOSS +C MEASUREMENTS. +C +C IF THE SAME ABSORBER WAS USED BEFORE , GO TO STATEMENT # 55 + + IF(A2.EQ.A2SAV.AND.Z2.EQ.Z2SAV) GOTO 55 + + Z2SAV=Z2 + A2SAV=A2 + +C FUNCTION Y + + FY=54721.*(1.+5.15E-2*SQRT(A2/RHO)-EXP(-0.23*Z2)) + IF(IFG.NE.1) GOTO 10 + FY=54721.*(1.35-EXP(Z2*(-.13+.0014*Z2))) + +C G(XI) IS THE DERIVATION OF A GASSIAN WITH VARIABLE HEIGHT H(Z2). + +10 IF(Z2.GT.26.) GOTO 20 + G1=19.84*EXP(-.17*(Z2-4.25)**2) + GOTO 35 +20 G1=0.000001 + IF(Z2.GT.38.) GOTO 40 +35 G2=17.12*EXP(-.12*(Z2-11.63)**2) + GOTO 50 +40 G2=0.0000001 +50 G3=7.95*EXP(-.015*(Z2-30.2)**2) + G4=5.84*EXP(-.022*(Z2-48.63)**2) + G5=7.27*EXP(-.005*(Z2-73.06)**2) + HZ2=(9.-(G1+G2+G3+G4+G5))*1.32E-5 + ZWD=2./3. + Z2ZWD=Z2**ZWD + +C MULTIPLICATIONFACTORS OF G(XI) + + FG=1.2E-4*Z2*Z2+2.49E-2*A2/RHO + IF(IFG.NE.1) GOTO 52 + FG=1.3/(1.+EXP(3.-Z2/5.)) +52 ALEFG=ALOG(2.7E-5/FG) + +C CALCULATION OF G(XI) + +55 GXI=0. + IF(XI.GE.1.E-9.AND.XI.LE.5.E-4) THEN + + SQXI=SQRT(XI) + C=2./Z2*SQXI/(1.+1.E4*SQXI) + IF(IFG.EQ.1) C=C/2. + FG0=1./(1.+(XI*10000.)**3) + AL=ALOG(XI)-ALEFG + GXI=(C-HZ2*AL*EXP(-.32*AL*AL))*FG0 + ENDIF + +C CALCULATION OF Y(XI) + Y=3.3E-4*ALOG(1.+XI*FY)+GXI +C ENERGY LOSS OF HEAVY IONS +C EFFECTIVE CHARGE + VV0=V*137. + FV=1. + IF(V.LE..62) FV=1.-EXP(-VV0) + AZ1=ALOG(1.035-.4*EXP(-.16*Z1)) + + QQ=V/Z1**.509 + GHI=Z1 + VZ1=(-116.79-3350.4*QQ)*QQ + IF(VZ1.GT.-85.2) GHI=Z1*(1.-EXP(VZ1)) + IF(Z1.GT.2.) GHI=Z1*(1.-EXP(FV*AZ1-0.879*VV0/Z1**0.65)) + +C EFFECTIVE CHARGE FOR PROTONS AND ALPHA PARTICLES + +C ******************** RESULTS ******************** + +C ELECTRONIC ENERGY LOSS DEDXHI + + DEDXHI=GHI*GHI*Z2*Y/(A2*V**2) + +C NUCLEAR ENERGY LOSS DEDXNU + + ZA=SQRT(Z1**(ZWD)+Z2ZWD) + EPS=3.25E4*A2*ENER/(Z1*Z2*(A1+A2)*ZA) + SIGMAN=1.7*SQRT(EPS)*ALOG(EPS+2.1718282)/ + 1 (1.+6.8*EPS+3.4*EPS**1.5) + DEDXNU=SIGMAN*5.105*Z1*Z2*A1/(ZA*A2*(A1+A2)) + +C TOTAL ENERGY LOSS DEDXTO + + DEDXTO=DEDXHI+DEDXNU + + RETURN + END +c diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/desorb.out b/anasen_analysis_vignesh/eloss_calculations/stopit/desorb.out new file mode 100644 index 0000000..ed1117c --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/desorb.out @@ -0,0 +1,88435 @@ + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.123 ENERGY OUT = 0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.223 ENERGY OUT = 0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 0.523 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 0.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 5.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 6.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 7.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 8.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.523 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 9.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 10.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.523 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.623 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 11.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.423 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.623 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 12.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.423 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.523 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 13.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.423 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.823 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 14.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.023 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.623 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 15.923 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.023 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.223 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.423 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.623 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 16.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.023 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.323 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.623 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.823 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 17.923 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.223 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.323 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.623 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.823 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 18.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.223 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.423 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.623 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.823 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 19.923 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.023 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.223 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.623 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 20.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.623 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 21.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 21.823 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 21.923 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.023 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.123 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.223 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.323 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.423 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.523 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.623 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.723 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.823 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 22.923 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.023 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.123 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.223 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.323 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.423 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.523 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.623 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.723 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.823 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 23.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.123 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.223 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.323 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.423 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.623 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.723 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.823 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 24.923 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.023 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.223 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.323 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.423 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.523 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.623 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.723 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.823 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 25.923 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.023 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.223 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.323 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.423 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.523 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.823 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 26.923 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.223 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.323 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.523 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.723 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.823 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 27.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.023 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.223 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.423 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.523 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.623 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.823 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 28.923 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.023 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.223 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.423 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.523 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.623 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.723 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.823 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 29.923 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.023 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.123 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.223 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.323 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.423 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.623 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.823 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 30.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.023 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.123 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.223 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.423 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.523 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.623 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.823 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 31.923 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 32.023 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 32.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 32.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 32.323 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 32.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 32.523 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 32.623 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 32.723 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 32.823 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 32.923 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.023 ENERGY OUT = -0.007(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.123 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.223 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.323 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.423 ENERGY OUT = -0.007(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.523 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.623 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.723 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.823 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 33.923 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.023 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.123 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.323 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.423 ENERGY OUT = -0.011(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.523 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.623 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.723 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.823 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 34.923 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.023 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.123 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.223 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.323 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.423 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.523 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.623 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.723 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.823 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 35.923 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.023 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.123 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.223 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.323 ENERGY OUT = -0.007(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.423 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.523 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.623 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.723 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.823 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 36.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.023 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.123 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.223 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.323 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.523 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.623 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.723 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 37.923 ENERGY OUT = -0.007(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.023 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.123 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.223 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.323 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.423 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.523 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.623 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.723 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.823 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 38.923 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.023 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.123 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.223 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.323 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.423 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.523 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.623 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.823 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 39.923 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.023 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.123 ENERGY OUT = -0.007(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.223 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.323 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.423 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.523 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.623 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.723 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.823 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 40.923 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.023 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.123 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.223 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.323 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.423 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.523 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.623 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.723 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.823 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 41.923 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.023 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.123 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.223 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.323 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.423 ENERGY OUT = -0.011(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.523 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.623 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.723 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.823 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 42.923 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.023 ENERGY OUT = -0.004(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.123 ENERGY OUT = -0.003(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.223 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.323 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.423 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.523 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.623 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.723 ENERGY OUT = -0.005(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 43.923 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.023 ENERGY OUT = -0.007(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.123 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.223 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.323 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.423 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.523 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.623 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.723 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.823 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 44.923 ENERGY OUT = -0.008(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.023 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.123 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.223 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.323 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.423 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.523 ENERGY OUT = -0.009(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.623 ENERGY OUT = -0.010(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.723 ENERGY OUT = -0.002(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.823 ENERGY OUT = -0.006(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 0.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 2 STEPS ENERGY IN = 0.000 ENERGY OUT = NaN(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 45.923 ENERGY OUT = 1.041(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 1.04100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 1.041 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.023 ENERGY OUT = 2.078(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.07800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.078 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.123 ENERGY OUT = 2.886(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 2.88600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 2.886 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.223 ENERGY OUT = 3.577(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 3.57700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 3.577 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.323 ENERGY OUT = 4.194(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.19400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.194 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.423 ENERGY OUT = 4.757(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 4.75700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-**** STEPS ENERGY IN = 4.757 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.523 ENERGY OUT = 5.280(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.28000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 5.280 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.623 ENERGY OUT = 5.771(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 5.77100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 5.771 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.723 ENERGY OUT = 6.236(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.23600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 6.236 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.823 ENERGY OUT = 6.679(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 6.67900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 6.679 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 46.923 ENERGY OUT = 7.104(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.10400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-8192 STEPS ENERGY IN = 7.104 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.023 ENERGY OUT = 7.512(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.51200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 7.512 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.123 ENERGY OUT = 7.906(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 7.90600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 7.906 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.223 ENERGY OUT = 8.287(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.28700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 8.287 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.323 ENERGY OUT = 8.657(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 8.65700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 8.657 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.423 ENERGY OUT = 9.016(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.01600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 9.016 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.523 ENERGY OUT = 9.366(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.36600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 9.366 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.623 ENERGY OUT = 9.708(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 9.70800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 9.708 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.723 ENERGY OUT = 10.041(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.04100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 10.041 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.823 ENERGY OUT = 10.368(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.36800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 10.368 ENERGY OUT = -0.001(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 47.923 ENERGY OUT = 10.687(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 10.68700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 10.687 ENERGY OUT = -0.000(MEV) + CHARGED PARTICLE STOPPED IN LAYER # 1 + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 48.023 ENERGY OUT = 11.001(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.00100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 11.001 ENERGY OUT = 0.067(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 48.123 ENERGY OUT = 11.308(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.30800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 11.308 ENERGY OUT = 1.372(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 48.223 ENERGY OUT = 11.610(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.61000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 11.610 ENERGY OUT = 2.364(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 48.323 ENERGY OUT = 11.907(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 11.90700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 11.907 ENERGY OUT = 3.156(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 48.423 ENERGY OUT = 12.199(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.19900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 12.199 ENERGY OUT = 3.841(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-4096 STEPS ENERGY IN = 48.523 ENERGY OUT = 12.486(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.48600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 12.486 ENERGY OUT = 4.454(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 48.623 ENERGY OUT = 12.778(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 12.77800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 12.778 ENERGY OUT = 5.035(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 48.723 ENERGY OUT = 13.057(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.05700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 13.057 ENERGY OUT = 5.559(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 48.823 ENERGY OUT = 13.332(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.33200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 13.332 ENERGY OUT = 6.053(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 48.923 ENERGY OUT = 13.603(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.60300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 13.603 ENERGY OUT = 6.520(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.023 ENERGY OUT = 13.871(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 13.87100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 13.871 ENERGY OUT = 6.967(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.123 ENERGY OUT = 14.135(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.13500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 14.135 ENERGY OUT = 7.395(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.223 ENERGY OUT = 14.396(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.39600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 14.396 ENERGY OUT = 7.807(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.323 ENERGY OUT = 14.655(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.65500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 14.655 ENERGY OUT = 8.206(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.423 ENERGY OUT = 14.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 14.91000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 14.910 ENERGY OUT = 8.591(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.523 ENERGY OUT = 15.162(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.16200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 15.162 ENERGY OUT = 8.964(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.623 ENERGY OUT = 15.412(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.41200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 15.412 ENERGY OUT = 9.329(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.723 ENERGY OUT = 15.659(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.65900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 15.659 ENERGY OUT = 9.683(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.823 ENERGY OUT = 15.903(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 15.90300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 15.903 ENERGY OUT = 10.028(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 49.923 ENERGY OUT = 16.145(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.14500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 16.145 ENERGY OUT = 10.366(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.023 ENERGY OUT = 16.385(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.38500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 16.385 ENERGY OUT = 10.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.123 ENERGY OUT = 16.623(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 16.623 ENERGY OUT = 11.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.223 ENERGY OUT = 16.859(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 16.85900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 16.859 ENERGY OUT = 11.340(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.323 ENERGY OUT = 17.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.09200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 17.092 ENERGY OUT = 11.651(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.423 ENERGY OUT = 17.323(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 17.323 ENERGY OUT = 11.957(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.523 ENERGY OUT = 17.553(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.55300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 17.553 ENERGY OUT = 12.259(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.623 ENERGY OUT = 17.780(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 17.78000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 17.780 ENERGY OUT = 12.555(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.723 ENERGY OUT = 18.006(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.00600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 18.006 ENERGY OUT = 12.847(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.823 ENERGY OUT = 18.230(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.23000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 18.230 ENERGY OUT = 13.134(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 50.923 ENERGY OUT = 18.452(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.45200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 18.452 ENERGY OUT = 13.417(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.023 ENERGY OUT = 18.673(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.67300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 18.673 ENERGY OUT = 13.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.123 ENERGY OUT = 18.892(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 18.89200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 18.892 ENERGY OUT = 13.972(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.223 ENERGY OUT = 19.109(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.10900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 19.109 ENERGY OUT = 14.244(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.323 ENERGY OUT = 19.325(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.32500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 19.325 ENERGY OUT = 14.512(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.423 ENERGY OUT = 19.539(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.53900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 19.539 ENERGY OUT = 14.777(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.523 ENERGY OUT = 19.752(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.75200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 19.752 ENERGY OUT = 15.040(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.623 ENERGY OUT = 19.964(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 19.96400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 19.964 ENERGY OUT = 15.299(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.723 ENERGY OUT = 20.174(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.17400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 20.174 ENERGY OUT = 15.556(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.823 ENERGY OUT = 20.383(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.38300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 20.383 ENERGY OUT = 15.810(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 51.923 ENERGY OUT = 20.590(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.59000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 20.590 ENERGY OUT = 16.060(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.023 ENERGY OUT = 20.797(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 20.79700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 20.797 ENERGY OUT = 16.309(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.123 ENERGY OUT = 21.002(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.00200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 21.002 ENERGY OUT = 16.555(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.223 ENERGY OUT = 21.206(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.20600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 21.206 ENERGY OUT = 16.799(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.323 ENERGY OUT = 21.408(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.40800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 21.408 ENERGY OUT = 17.040(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.423 ENERGY OUT = 21.609(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.60900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 21.609 ENERGY OUT = 17.279(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.523 ENERGY OUT = 21.810(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 21.81000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 21.810 ENERGY OUT = 17.517(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.623 ENERGY OUT = 22.009(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.00900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 22.009 ENERGY OUT = 17.752(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.723 ENERGY OUT = 22.207(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.20700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 22.207 ENERGY OUT = 17.985(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.823 ENERGY OUT = 22.404(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.40400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 22.404 ENERGY OUT = 18.216(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 52.923 ENERGY OUT = 22.601(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.60100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 22.601 ENERGY OUT = 18.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.023 ENERGY OUT = 22.796(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.79600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 22.796 ENERGY OUT = 18.674(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.123 ENERGY OUT = 22.990(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 22.99000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 22.990 ENERGY OUT = 18.899(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.223 ENERGY OUT = 23.183(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.18300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 23.183 ENERGY OUT = 19.123(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.323 ENERGY OUT = 23.375(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.37500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 23.375 ENERGY OUT = 19.345(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.423 ENERGY OUT = 23.566(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.56600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 23.566 ENERGY OUT = 19.566(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.523 ENERGY OUT = 23.757(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.75700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 23.757 ENERGY OUT = 19.786(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.623 ENERGY OUT = 23.946(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 23.94600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 23.946 ENERGY OUT = 20.003(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.723 ENERGY OUT = 24.135(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.13500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 24.135 ENERGY OUT = 20.220(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.823 ENERGY OUT = 24.323(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 24.323 ENERGY OUT = 20.435(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 53.923 ENERGY OUT = 24.510(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.51000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 24.510 ENERGY OUT = 20.649(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.023 ENERGY OUT = 24.696(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.69600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 24.696 ENERGY OUT = 20.861(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.123 ENERGY OUT = 24.881(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 24.88100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 24.881 ENERGY OUT = 21.071(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.223 ENERGY OUT = 25.066(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.06600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 25.066 ENERGY OUT = 21.281(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.323 ENERGY OUT = 25.250(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.25000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 25.250 ENERGY OUT = 21.490(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.423 ENERGY OUT = 25.433(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.43300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 25.433 ENERGY OUT = 21.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.523 ENERGY OUT = 25.615(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.61500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 25.615 ENERGY OUT = 21.902(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.623 ENERGY OUT = 25.796(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.79600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 25.796 ENERGY OUT = 22.107(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.723 ENERGY OUT = 25.977(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 25.97700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 25.977 ENERGY OUT = 22.310(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.823 ENERGY OUT = 26.157(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.15700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 26.157 ENERGY OUT = 22.513(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 54.923 ENERGY OUT = 26.337(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.33700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 26.337 ENERGY OUT = 22.715(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.023 ENERGY OUT = 26.516(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.51600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 26.516 ENERGY OUT = 22.915(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.123 ENERGY OUT = 26.694(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.69400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 26.694 ENERGY OUT = 23.114(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.223 ENERGY OUT = 26.871(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 26.87100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 26.871 ENERGY OUT = 23.312(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.323 ENERGY OUT = 27.048(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.04800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 27.048 ENERGY OUT = 23.510(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.423 ENERGY OUT = 27.224(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.22400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 27.224 ENERGY OUT = 23.706(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.523 ENERGY OUT = 27.399(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.39900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 27.399 ENERGY OUT = 23.900(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.623 ENERGY OUT = 27.574(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.57400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 27.574 ENERGY OUT = 24.095(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.723 ENERGY OUT = 27.748(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.74800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 27.748 ENERGY OUT = 24.288(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.823 ENERGY OUT = 27.922(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 27.92200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 27.922 ENERGY OUT = 24.481(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 55.923 ENERGY OUT = 28.095(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.09500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 28.095 ENERGY OUT = 24.672(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.023 ENERGY OUT = 28.268(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.26800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 28.268 ENERGY OUT = 24.863(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.123 ENERGY OUT = 28.439(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.43900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 28.439 ENERGY OUT = 25.052(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.223 ENERGY OUT = 28.611(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.61100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 28.611 ENERGY OUT = 25.242(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.323 ENERGY OUT = 28.782(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.78200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 28.782 ENERGY OUT = 25.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.423 ENERGY OUT = 28.952(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 28.95200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 28.952 ENERGY OUT = 25.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.523 ENERGY OUT = 29.122(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.12200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 29.122 ENERGY OUT = 25.804(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.623 ENERGY OUT = 29.291(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.29100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 29.291 ENERGY OUT = 25.990(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.723 ENERGY OUT = 29.460(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.46000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 29.460 ENERGY OUT = 26.175(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.823 ENERGY OUT = 29.628(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.62800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 29.628 ENERGY OUT = 26.360(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 56.923 ENERGY OUT = 29.795(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.79500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 29.795 ENERGY OUT = 26.542(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.023 ENERGY OUT = 29.963(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 29.96300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 29.963 ENERGY OUT = 26.726(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.123 ENERGY OUT = 30.129(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.12900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 30.129 ENERGY OUT = 26.908(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.223 ENERGY OUT = 30.296(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.29600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 30.296 ENERGY OUT = 27.090(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.323 ENERGY OUT = 30.461(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.46100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 30.461 ENERGY OUT = 27.270(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.423 ENERGY OUT = 30.627(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.62700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 30.627 ENERGY OUT = 27.451(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.523 ENERGY OUT = 30.791(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.79100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 30.791 ENERGY OUT = 27.629(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.623 ENERGY OUT = 30.956(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 30.95600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 30.956 ENERGY OUT = 27.809(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.723 ENERGY OUT = 31.119(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.11900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 31.119 ENERGY OUT = 27.986(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.823 ENERGY OUT = 31.283(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.28300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 31.283 ENERGY OUT = 28.164(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 57.923 ENERGY OUT = 31.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.44600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 31.446 ENERGY OUT = 28.341(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.023 ENERGY OUT = 31.608(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.60800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 31.608 ENERGY OUT = 28.517(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.123 ENERGY OUT = 31.770(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.77000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 31.770 ENERGY OUT = 28.692(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.223 ENERGY OUT = 31.932(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 31.93200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 31.932 ENERGY OUT = 28.868(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.323 ENERGY OUT = 32.093(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.09300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 32.093 ENERGY OUT = 29.042(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.423 ENERGY OUT = 32.254(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.25400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 32.254 ENERGY OUT = 29.216(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.523 ENERGY OUT = 32.415(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.41500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 32.415 ENERGY OUT = 29.390(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.623 ENERGY OUT = 32.575(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.57500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 32.575 ENERGY OUT = 29.562(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.723 ENERGY OUT = 32.735(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.73500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 32.735 ENERGY OUT = 29.735(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.823 ENERGY OUT = 32.894(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 32.89400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 32.894 ENERGY OUT = 29.906(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 58.923 ENERGY OUT = 33.053(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.05300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 33.053 ENERGY OUT = 30.078(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.023 ENERGY OUT = 33.211(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.21100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 33.211 ENERGY OUT = 30.248(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.123 ENERGY OUT = 33.369(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.36900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 33.369 ENERGY OUT = 30.418(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.223 ENERGY OUT = 33.527(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.52700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 33.527 ENERGY OUT = 30.588(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.323 ENERGY OUT = 33.684(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.68400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 33.684 ENERGY OUT = 30.756(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.423 ENERGY OUT = 33.842(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.84200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 33.842 ENERGY OUT = 30.926(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.523 ENERGY OUT = 33.998(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 33.99800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 33.998 ENERGY OUT = 31.093(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.623 ENERGY OUT = 34.154(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.15400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 34.154 ENERGY OUT = 31.261(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.723 ENERGY OUT = 34.310(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.31000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 34.310 ENERGY OUT = 31.428(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.823 ENERGY OUT = 34.466(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.46600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 34.466 ENERGY OUT = 31.595(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 59.923 ENERGY OUT = 34.621(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.62100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 34.621 ENERGY OUT = 31.761(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.023 ENERGY OUT = 34.776(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.77600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 34.776 ENERGY OUT = 31.927(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.123 ENERGY OUT = 34.931(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 34.93100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 34.931 ENERGY OUT = 32.093(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.223 ENERGY OUT = 35.085(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.08500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 35.085 ENERGY OUT = 32.257(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.323 ENERGY OUT = 35.239(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.23900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 35.239 ENERGY OUT = 32.422(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.423 ENERGY OUT = 35.393(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.39300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 35.393 ENERGY OUT = 32.586(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.523 ENERGY OUT = 35.546(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.54600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 35.546 ENERGY OUT = 32.749(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.623 ENERGY OUT = 35.699(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.69900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 35.699 ENERGY OUT = 32.912(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.723 ENERGY OUT = 35.852(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 35.85200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 35.852 ENERGY OUT = 33.076(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.823 ENERGY OUT = 36.004(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.00400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 36.004 ENERGY OUT = 33.238(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 60.923 ENERGY OUT = 36.156(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.15600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 36.156 ENERGY OUT = 33.399(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.023 ENERGY OUT = 36.308(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.30800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 36.308 ENERGY OUT = 33.561(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.123 ENERGY OUT = 36.459(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.45900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 36.459 ENERGY OUT = 33.722(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.223 ENERGY OUT = 36.610(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.61000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 36.610 ENERGY OUT = 33.882(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.323 ENERGY OUT = 36.761(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.76100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 36.761 ENERGY OUT = 34.043(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.423 ENERGY OUT = 36.912(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 36.91200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 36.912 ENERGY OUT = 34.203(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.523 ENERGY OUT = 37.062(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.06200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 37.062 ENERGY OUT = 34.363(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.623 ENERGY OUT = 37.212(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.21200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 37.212 ENERGY OUT = 34.522(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.723 ENERGY OUT = 37.362(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.36200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 37.362 ENERGY OUT = 34.681(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.823 ENERGY OUT = 37.511(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.51100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 37.511 ENERGY OUT = 34.839(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 61.923 ENERGY OUT = 37.661(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.66100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 37.661 ENERGY OUT = 34.998(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.023 ENERGY OUT = 37.810(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.81000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 37.810 ENERGY OUT = 35.156(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.123 ENERGY OUT = 37.958(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 37.95800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 37.958 ENERGY OUT = 35.313(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.223 ENERGY OUT = 38.106(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.10600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 38.106 ENERGY OUT = 35.469(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.323 ENERGY OUT = 38.255(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.25500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 38.255 ENERGY OUT = 35.627(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.423 ENERGY OUT = 38.402(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.40200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 38.402 ENERGY OUT = 35.782(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.523 ENERGY OUT = 38.550(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.55000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 38.550 ENERGY OUT = 35.939(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.623 ENERGY OUT = 38.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.69700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 38.697 ENERGY OUT = 36.094(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.723 ENERGY OUT = 38.844(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.84400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 38.844 ENERGY OUT = 36.250(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.823 ENERGY OUT = 38.991(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 38.99100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 38.991 ENERGY OUT = 36.405(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 62.923 ENERGY OUT = 39.138(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.13800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 39.138 ENERGY OUT = 36.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.023 ENERGY OUT = 39.284(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.28400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 39.284 ENERGY OUT = 36.714(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.123 ENERGY OUT = 39.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.43000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 39.430 ENERGY OUT = 36.868(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.223 ENERGY OUT = 39.576(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.57600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 39.576 ENERGY OUT = 37.022(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.323 ENERGY OUT = 39.722(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.72200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 39.722 ENERGY OUT = 37.176(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.423 ENERGY OUT = 39.867(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 39.86700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 39.867 ENERGY OUT = 37.329(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.523 ENERGY OUT = 40.012(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.01200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 40.012 ENERGY OUT = 37.482(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.623 ENERGY OUT = 40.157(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.15700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 40.157 ENERGY OUT = 37.634(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.723 ENERGY OUT = 40.302(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.30200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 40.302 ENERGY OUT = 37.787(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.823 ENERGY OUT = 40.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.44600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 40.446 ENERGY OUT = 37.938(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 63.923 ENERGY OUT = 40.590(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.59000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 40.590 ENERGY OUT = 38.090(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.023 ENERGY OUT = 40.734(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.73400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 40.734 ENERGY OUT = 38.241(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.123 ENERGY OUT = 40.878(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 40.87800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 40.878 ENERGY OUT = 38.393(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.223 ENERGY OUT = 41.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.02100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 41.021 ENERGY OUT = 38.543(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.323 ENERGY OUT = 41.165(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.16500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 41.165 ENERGY OUT = 38.694(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.423 ENERGY OUT = 41.308(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.30800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 41.308 ENERGY OUT = 38.845(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.523 ENERGY OUT = 41.451(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.45100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 41.451 ENERGY OUT = 38.995(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.623 ENERGY OUT = 41.594(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.59400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 41.594 ENERGY OUT = 39.145(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.723 ENERGY OUT = 41.736(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.73600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 41.736 ENERGY OUT = 39.294(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.823 ENERGY OUT = 41.878(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 41.87800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 41.878 ENERGY OUT = 39.443(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 64.923 ENERGY OUT = 42.020(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.02000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 42.020 ENERGY OUT = 39.592(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.023 ENERGY OUT = 42.162(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.16200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 42.162 ENERGY OUT = 39.741(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.123 ENERGY OUT = 42.304(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.30400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 42.304 ENERGY OUT = 39.889(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.223 ENERGY OUT = 42.445(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.44500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 42.445 ENERGY OUT = 40.037(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.323 ENERGY OUT = 42.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.58700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 42.587 ENERGY OUT = 40.186(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.423 ENERGY OUT = 42.728(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.72800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 42.728 ENERGY OUT = 40.333(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.523 ENERGY OUT = 42.869(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 42.86900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 42.869 ENERGY OUT = 40.481(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.623 ENERGY OUT = 43.009(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.00900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.009 ENERGY OUT = 40.628(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.723 ENERGY OUT = 43.150(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.15000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.150 ENERGY OUT = 40.775(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.823 ENERGY OUT = 43.290(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.29000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.290 ENERGY OUT = 40.922(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 65.923 ENERGY OUT = 43.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.43000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.430 ENERGY OUT = 41.068(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.023 ENERGY OUT = 43.570(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.57000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.570 ENERGY OUT = 41.214(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.123 ENERGY OUT = 43.710(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.71000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.710 ENERGY OUT = 41.361(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.223 ENERGY OUT = 43.849(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.84900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.849 ENERGY OUT = 41.506(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.323 ENERGY OUT = 43.989(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 43.98900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 43.989 ENERGY OUT = 41.652(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.423 ENERGY OUT = 44.128(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.12800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 44.128 ENERGY OUT = 41.797(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.523 ENERGY OUT = 44.267(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.26700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 44.267 ENERGY OUT = 41.942(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.623 ENERGY OUT = 44.406(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.40600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 44.406 ENERGY OUT = 42.088(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.723 ENERGY OUT = 44.544(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.54400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 44.544 ENERGY OUT = 42.232(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.823 ENERGY OUT = 44.683(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.68300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 44.683 ENERGY OUT = 42.377(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 66.923 ENERGY OUT = 44.821(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.82100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 44.821 ENERGY OUT = 42.521(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.023 ENERGY OUT = 44.959(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 44.95900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 44.959 ENERGY OUT = 42.664(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.123 ENERGY OUT = 45.097(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.09700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 45.097 ENERGY OUT = 42.808(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.223 ENERGY OUT = 45.235(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.23500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 45.235 ENERGY OUT = 42.952(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.323 ENERGY OUT = 45.372(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.37200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 45.372 ENERGY OUT = 43.095(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.423 ENERGY OUT = 45.510(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.51000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 45.510 ENERGY OUT = 43.239(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.523 ENERGY OUT = 45.647(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.64700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 45.647 ENERGY OUT = 43.381(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.623 ENERGY OUT = 45.784(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.78400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 45.784 ENERGY OUT = 43.524(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.723 ENERGY OUT = 45.921(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 45.92100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 45.921 ENERGY OUT = 43.667(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.823 ENERGY OUT = 46.058(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.05800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 46.058 ENERGY OUT = 43.809(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 67.923 ENERGY OUT = 46.195(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.19500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 46.195 ENERGY OUT = 43.952(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.023 ENERGY OUT = 46.331(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.33100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 46.331 ENERGY OUT = 44.093(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.123 ENERGY OUT = 46.467(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.46700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 46.467 ENERGY OUT = 44.235(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.223 ENERGY OUT = 46.604(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.60400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 46.604 ENERGY OUT = 44.377(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.323 ENERGY OUT = 46.740(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.74000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 46.740 ENERGY OUT = 44.519(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.423 ENERGY OUT = 46.875(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 46.87500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 46.875 ENERGY OUT = 44.659(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.523 ENERGY OUT = 47.011(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.01100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.011 ENERGY OUT = 44.801(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.623 ENERGY OUT = 47.146(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.14600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.146 ENERGY OUT = 44.941(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.723 ENERGY OUT = 47.282(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.28200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.282 ENERGY OUT = 45.082(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.823 ENERGY OUT = 47.417(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.41700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.417 ENERGY OUT = 45.222(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 68.923 ENERGY OUT = 47.552(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.55200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.552 ENERGY OUT = 45.363(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.023 ENERGY OUT = 47.687(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.68700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.687 ENERGY OUT = 45.503(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.123 ENERGY OUT = 47.822(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.82200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.822 ENERGY OUT = 45.643(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.223 ENERGY OUT = 47.956(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 47.95600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 47.956 ENERGY OUT = 45.782(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.323 ENERGY OUT = 48.091(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.09100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 48.091 ENERGY OUT = 45.922(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.423 ENERGY OUT = 48.225(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.22500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 48.225 ENERGY OUT = 46.061(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.523 ENERGY OUT = 48.360(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.36000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 48.360 ENERGY OUT = 46.201(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.623 ENERGY OUT = 48.494(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.49400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 48.494 ENERGY OUT = 46.340(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.723 ENERGY OUT = 48.628(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.62800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 48.628 ENERGY OUT = 46.479(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.823 ENERGY OUT = 48.761(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.76100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 48.761 ENERGY OUT = 46.617(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 69.923 ENERGY OUT = 48.895(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 48.89500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 48.895 ENERGY OUT = 46.756(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.023 ENERGY OUT = 49.029(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.02900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.029 ENERGY OUT = 46.895(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.123 ENERGY OUT = 49.162(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.16200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.162 ENERGY OUT = 47.033(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.223 ENERGY OUT = 49.295(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.29500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.295 ENERGY OUT = 47.170(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.323 ENERGY OUT = 49.428(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.42800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.428 ENERGY OUT = 47.308(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.423 ENERGY OUT = 49.561(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.56100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.561 ENERGY OUT = 47.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.523 ENERGY OUT = 49.694(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.69400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.694 ENERGY OUT = 47.584(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.623 ENERGY OUT = 49.827(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.82700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.827 ENERGY OUT = 47.721(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.723 ENERGY OUT = 49.959(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 49.95900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 49.959 ENERGY OUT = 47.858(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.823 ENERGY OUT = 50.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.09200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 50.092 ENERGY OUT = 47.996(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 70.923 ENERGY OUT = 50.224(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.22400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 50.224 ENERGY OUT = 48.132(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.023 ENERGY OUT = 50.356(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.35600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 50.356 ENERGY OUT = 48.269(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.123 ENERGY OUT = 50.488(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.48800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 50.488 ENERGY OUT = 48.405(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.223 ENERGY OUT = 50.620(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.62000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 50.620 ENERGY OUT = 48.542(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.323 ENERGY OUT = 50.752(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.75200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 50.752 ENERGY OUT = 48.679(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.423 ENERGY OUT = 50.884(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 50.88400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 50.884 ENERGY OUT = 48.815(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.523 ENERGY OUT = 51.016(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.01600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.016 ENERGY OUT = 48.951(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.623 ENERGY OUT = 51.147(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.14700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.147 ENERGY OUT = 49.087(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-2048 STEPS ENERGY IN = 71.723 ENERGY OUT = 51.278(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.27800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.278 ENERGY OUT = 49.222(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 71.823 ENERGY OUT = 51.411(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.41100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.411 ENERGY OUT = 49.360(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 71.923 ENERGY OUT = 51.542(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.54200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.542 ENERGY OUT = 49.495(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.023 ENERGY OUT = 51.673(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.67300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.673 ENERGY OUT = 49.630(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.123 ENERGY OUT = 51.804(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.80400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.804 ENERGY OUT = 49.766(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.223 ENERGY OUT = 51.935(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 51.93500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 51.935 ENERGY OUT = 49.901(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.323 ENERGY OUT = 52.065(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.06500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.065 ENERGY OUT = 50.035(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.423 ENERGY OUT = 52.196(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.19600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.196 ENERGY OUT = 50.170(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.523 ENERGY OUT = 52.326(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.32600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.326 ENERGY OUT = 50.305(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.623 ENERGY OUT = 52.456(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.45600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.456 ENERGY OUT = 50.439(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.723 ENERGY OUT = 52.586(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.58600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.586 ENERGY OUT = 50.573(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.823 ENERGY OUT = 52.717(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.71700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.717 ENERGY OUT = 50.708(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 72.923 ENERGY OUT = 52.846(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.84600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.846 ENERGY OUT = 50.841(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.023 ENERGY OUT = 52.976(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 52.97600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 52.976 ENERGY OUT = 50.975(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.123 ENERGY OUT = 53.106(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.10600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 53.106 ENERGY OUT = 51.109(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.223 ENERGY OUT = 53.236(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.23600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 53.236 ENERGY OUT = 51.243(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.323 ENERGY OUT = 53.365(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.36500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 53.365 ENERGY OUT = 51.377(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.423 ENERGY OUT = 53.494(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.49400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 53.494 ENERGY OUT = 51.510(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.523 ENERGY OUT = 53.624(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.62400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 53.624 ENERGY OUT = 51.644(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.623 ENERGY OUT = 53.753(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.75300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 53.753 ENERGY OUT = 51.777(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.723 ENERGY OUT = 53.882(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 53.88200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 53.882 ENERGY OUT = 51.909(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.823 ENERGY OUT = 54.011(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.01100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.011 ENERGY OUT = 52.042(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 73.923 ENERGY OUT = 54.140(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.14000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.140 ENERGY OUT = 52.175(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.023 ENERGY OUT = 54.268(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.26800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.268 ENERGY OUT = 52.307(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.123 ENERGY OUT = 54.397(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.39700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.397 ENERGY OUT = 52.440(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.223 ENERGY OUT = 54.525(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.52500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.525 ENERGY OUT = 52.572(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.323 ENERGY OUT = 54.654(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.65400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.654 ENERGY OUT = 52.705(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.423 ENERGY OUT = 54.782(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.78200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.782 ENERGY OUT = 52.837(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.523 ENERGY OUT = 54.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 54.91000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 54.910 ENERGY OUT = 52.968(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.623 ENERGY OUT = 55.039(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.03900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.039 ENERGY OUT = 53.101(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.723 ENERGY OUT = 55.166(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.16600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.166 ENERGY OUT = 53.232(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.823 ENERGY OUT = 55.294(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.29400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.294 ENERGY OUT = 53.364(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 74.923 ENERGY OUT = 55.422(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.42200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.422 ENERGY OUT = 53.495(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.023 ENERGY OUT = 55.550(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.55000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.550 ENERGY OUT = 53.627(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.123 ENERGY OUT = 55.678(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.67800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.678 ENERGY OUT = 53.759(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.223 ENERGY OUT = 55.805(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.80500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.805 ENERGY OUT = 53.889(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.323 ENERGY OUT = 55.933(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 55.93300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 55.933 ENERGY OUT = 54.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.423 ENERGY OUT = 56.060(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.06000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.060 ENERGY OUT = 54.152(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.523 ENERGY OUT = 56.187(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.18700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.187 ENERGY OUT = 54.282(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.623 ENERGY OUT = 56.314(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.31400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.314 ENERGY OUT = 54.413(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.723 ENERGY OUT = 56.441(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.44100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.441 ENERGY OUT = 54.543(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.823 ENERGY OUT = 56.568(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.56800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.568 ENERGY OUT = 54.674(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 75.923 ENERGY OUT = 56.695(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.69500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.695 ENERGY OUT = 54.804(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.023 ENERGY OUT = 56.822(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.82200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.822 ENERGY OUT = 54.935(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.123 ENERGY OUT = 56.948(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 56.94800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 56.948 ENERGY OUT = 55.064(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.223 ENERGY OUT = 57.075(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.07500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 57.075 ENERGY OUT = 55.195(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.323 ENERGY OUT = 57.202(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.20200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 57.202 ENERGY OUT = 55.325(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.423 ENERGY OUT = 57.328(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.32800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 57.328 ENERGY OUT = 55.455(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.523 ENERGY OUT = 57.454(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.45400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 57.454 ENERGY OUT = 55.584(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.623 ENERGY OUT = 57.581(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.58100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 57.581 ENERGY OUT = 55.715(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.723 ENERGY OUT = 57.707(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.70700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 57.707 ENERGY OUT = 55.844(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.823 ENERGY OUT = 57.833(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.83300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 57.833 ENERGY OUT = 55.973(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 76.923 ENERGY OUT = 57.959(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 57.95900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 57.959 ENERGY OUT = 56.103(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.023 ENERGY OUT = 58.085(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.08500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.085 ENERGY OUT = 56.232(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.123 ENERGY OUT = 58.210(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.21000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.210 ENERGY OUT = 56.361(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.223 ENERGY OUT = 58.336(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.33600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.336 ENERGY OUT = 56.490(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.323 ENERGY OUT = 58.462(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.46200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.462 ENERGY OUT = 56.619(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.423 ENERGY OUT = 58.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.58700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.587 ENERGY OUT = 56.747(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.523 ENERGY OUT = 58.713(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.71300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.713 ENERGY OUT = 56.877(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.623 ENERGY OUT = 58.838(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.83800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.838 ENERGY OUT = 57.005(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.723 ENERGY OUT = 58.963(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 58.96300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 58.963 ENERGY OUT = 57.133(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.823 ENERGY OUT = 59.088(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.08800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.088 ENERGY OUT = 57.261(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 77.923 ENERGY OUT = 59.214(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.21400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.214 ENERGY OUT = 57.391(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.023 ENERGY OUT = 59.339(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.33900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.339 ENERGY OUT = 57.519(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.123 ENERGY OUT = 59.464(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.46400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.464 ENERGY OUT = 57.647(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.223 ENERGY OUT = 59.588(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.58800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.588 ENERGY OUT = 57.774(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.323 ENERGY OUT = 59.713(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.71300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.713 ENERGY OUT = 57.902(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.423 ENERGY OUT = 59.838(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.83800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.838 ENERGY OUT = 58.031(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.523 ENERGY OUT = 59.962(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 59.96200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 59.962 ENERGY OUT = 58.158(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.623 ENERGY OUT = 60.087(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.08700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.087 ENERGY OUT = 58.286(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.723 ENERGY OUT = 60.211(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.21100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.211 ENERGY OUT = 58.413(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.823 ENERGY OUT = 60.336(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.33600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.336 ENERGY OUT = 58.541(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 78.923 ENERGY OUT = 60.460(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.46000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.460 ENERGY OUT = 58.668(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.023 ENERGY OUT = 60.584(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.58400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.584 ENERGY OUT = 58.795(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.123 ENERGY OUT = 60.709(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.70900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.709 ENERGY OUT = 58.923(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.223 ENERGY OUT = 60.833(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.83300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.833 ENERGY OUT = 59.050(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.323 ENERGY OUT = 60.957(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 60.95700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 60.957 ENERGY OUT = 59.177(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.423 ENERGY OUT = 61.080(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.08000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.080 ENERGY OUT = 59.303(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.523 ENERGY OUT = 61.204(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.20400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.204 ENERGY OUT = 59.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.623 ENERGY OUT = 61.328(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.32800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.328 ENERGY OUT = 59.557(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.723 ENERGY OUT = 61.452(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.45200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.452 ENERGY OUT = 59.684(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.823 ENERGY OUT = 61.575(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.57500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.575 ENERGY OUT = 59.810(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 79.923 ENERGY OUT = 61.699(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.69900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.699 ENERGY OUT = 59.937(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.023 ENERGY OUT = 61.822(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.82200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.822 ENERGY OUT = 60.063(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.123 ENERGY OUT = 61.946(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 61.94600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 61.946 ENERGY OUT = 60.190(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.223 ENERGY OUT = 62.069(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.06900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.069 ENERGY OUT = 60.316(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.323 ENERGY OUT = 62.192(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.19200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.192 ENERGY OUT = 60.442(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.423 ENERGY OUT = 62.316(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.31600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.316 ENERGY OUT = 60.569(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.523 ENERGY OUT = 62.439(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.43900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.439 ENERGY OUT = 60.694(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.623 ENERGY OUT = 62.562(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.56200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.562 ENERGY OUT = 60.820(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.723 ENERGY OUT = 62.685(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.68500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.685 ENERGY OUT = 60.946(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.823 ENERGY OUT = 62.808(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.80800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.808 ENERGY OUT = 61.072(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 80.923 ENERGY OUT = 62.930(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 62.93000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 62.930 ENERGY OUT = 61.197(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.023 ENERGY OUT = 63.053(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.05300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.053 ENERGY OUT = 61.323(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.123 ENERGY OUT = 63.176(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.17600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.176 ENERGY OUT = 61.448(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.223 ENERGY OUT = 63.298(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.29800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.298 ENERGY OUT = 61.573(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.323 ENERGY OUT = 63.421(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.42100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.421 ENERGY OUT = 61.699(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.423 ENERGY OUT = 63.543(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.54300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.543 ENERGY OUT = 61.824(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.523 ENERGY OUT = 63.666(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.66600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.666 ENERGY OUT = 61.949(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.623 ENERGY OUT = 63.788(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.78800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.788 ENERGY OUT = 62.074(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.723 ENERGY OUT = 63.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 63.91000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 63.910 ENERGY OUT = 62.199(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.823 ENERGY OUT = 64.032(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.03200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.032 ENERGY OUT = 62.324(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 81.923 ENERGY OUT = 64.155(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.15500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.155 ENERGY OUT = 62.449(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.023 ENERGY OUT = 64.277(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.27700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.277 ENERGY OUT = 62.574(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.123 ENERGY OUT = 64.399(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.39900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.399 ENERGY OUT = 62.699(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.223 ENERGY OUT = 64.521(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.52100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.521 ENERGY OUT = 62.823(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.323 ENERGY OUT = 64.643(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.64300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.643 ENERGY OUT = 62.948(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.423 ENERGY OUT = 64.764(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.76400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.764 ENERGY OUT = 63.072(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.523 ENERGY OUT = 64.886(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 64.88600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 64.886 ENERGY OUT = 63.196(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.623 ENERGY OUT = 65.008(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.00800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.008 ENERGY OUT = 63.321(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.723 ENERGY OUT = 65.130(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.13000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.130 ENERGY OUT = 63.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.823 ENERGY OUT = 65.251(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.25100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.251 ENERGY OUT = 63.569(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 82.923 ENERGY OUT = 65.372(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.37200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.372 ENERGY OUT = 63.693(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.023 ENERGY OUT = 65.494(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.49400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.494 ENERGY OUT = 63.817(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.123 ENERGY OUT = 65.615(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.61500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.615 ENERGY OUT = 63.941(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.223 ENERGY OUT = 65.737(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.73700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.737 ENERGY OUT = 64.066(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.323 ENERGY OUT = 65.858(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.85800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.858 ENERGY OUT = 64.189(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.423 ENERGY OUT = 65.979(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 65.97900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 65.979 ENERGY OUT = 64.313(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.523 ENERGY OUT = 66.100(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.10000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.100 ENERGY OUT = 64.436(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.623 ENERGY OUT = 66.221(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.22100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.221 ENERGY OUT = 64.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.723 ENERGY OUT = 66.342(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.34200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.342 ENERGY OUT = 64.683(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.823 ENERGY OUT = 66.463(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.46300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.463 ENERGY OUT = 64.807(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 83.923 ENERGY OUT = 66.584(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.58400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.584 ENERGY OUT = 64.930(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.023 ENERGY OUT = 66.705(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.70500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.705 ENERGY OUT = 65.054(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.123 ENERGY OUT = 66.826(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.82600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.826 ENERGY OUT = 65.177(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.223 ENERGY OUT = 66.946(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 66.94600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 66.946 ENERGY OUT = 65.300(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.323 ENERGY OUT = 67.067(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.06700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.067 ENERGY OUT = 65.423(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.423 ENERGY OUT = 67.187(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.18700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.187 ENERGY OUT = 65.546(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.523 ENERGY OUT = 67.308(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.30800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.308 ENERGY OUT = 65.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.623 ENERGY OUT = 67.428(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.42800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.428 ENERGY OUT = 65.792(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.723 ENERGY OUT = 67.549(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.54900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.549 ENERGY OUT = 65.915(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.823 ENERGY OUT = 67.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.66900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.669 ENERGY OUT = 66.037(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 84.923 ENERGY OUT = 67.789(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.78900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.789 ENERGY OUT = 66.160(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.023 ENERGY OUT = 67.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 67.91000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 67.910 ENERGY OUT = 66.283(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.123 ENERGY OUT = 68.030(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.03000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.030 ENERGY OUT = 66.406(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.223 ENERGY OUT = 68.150(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.15000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.150 ENERGY OUT = 66.528(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.323 ENERGY OUT = 68.270(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.27000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.270 ENERGY OUT = 66.650(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.423 ENERGY OUT = 68.390(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.39000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.390 ENERGY OUT = 66.773(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.523 ENERGY OUT = 68.510(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.51000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.510 ENERGY OUT = 66.895(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.623 ENERGY OUT = 68.630(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.63000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.630 ENERGY OUT = 67.017(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.723 ENERGY OUT = 68.750(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.75000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.750 ENERGY OUT = 67.140(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.823 ENERGY OUT = 68.869(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.86900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.869 ENERGY OUT = 67.261(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 85.923 ENERGY OUT = 68.989(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 68.98900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 68.989 ENERGY OUT = 67.383(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.023 ENERGY OUT = 69.109(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.10900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.109 ENERGY OUT = 67.506(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.123 ENERGY OUT = 69.228(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.22800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.228 ENERGY OUT = 67.627(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.223 ENERGY OUT = 69.348(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.34800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.348 ENERGY OUT = 67.749(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.323 ENERGY OUT = 69.467(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.46700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.467 ENERGY OUT = 67.871(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.423 ENERGY OUT = 69.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.58700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.587 ENERGY OUT = 67.993(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.523 ENERGY OUT = 69.706(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.70600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.706 ENERGY OUT = 68.114(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.623 ENERGY OUT = 69.825(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.82500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.825 ENERGY OUT = 68.235(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.723 ENERGY OUT = 69.945(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 69.94500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 69.945 ENERGY OUT = 68.358(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.823 ENERGY OUT = 70.064(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.06400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.064 ENERGY OUT = 68.479(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 86.923 ENERGY OUT = 70.183(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.18300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.183 ENERGY OUT = 68.600(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.023 ENERGY OUT = 70.302(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.30200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.302 ENERGY OUT = 68.721(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.123 ENERGY OUT = 70.421(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.42100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.421 ENERGY OUT = 68.843(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.223 ENERGY OUT = 70.540(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.54000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.540 ENERGY OUT = 68.964(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.323 ENERGY OUT = 70.659(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.65900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.659 ENERGY OUT = 69.085(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.423 ENERGY OUT = 70.778(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.77800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.778 ENERGY OUT = 69.206(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.523 ENERGY OUT = 70.897(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 70.89700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 70.897 ENERGY OUT = 69.327(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.623 ENERGY OUT = 71.016(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.01600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.016 ENERGY OUT = 69.449(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.723 ENERGY OUT = 71.135(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.13500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.135 ENERGY OUT = 69.570(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.823 ENERGY OUT = 71.253(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.25300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.253 ENERGY OUT = 69.690(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 87.923 ENERGY OUT = 71.372(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.37200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.372 ENERGY OUT = 69.811(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.023 ENERGY OUT = 71.491(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.49100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.491 ENERGY OUT = 69.932(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.123 ENERGY OUT = 71.609(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.60900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.609 ENERGY OUT = 70.052(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.223 ENERGY OUT = 71.728(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.72800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.728 ENERGY OUT = 70.174(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.323 ENERGY OUT = 71.846(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.84600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.846 ENERGY OUT = 70.294(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.423 ENERGY OUT = 71.965(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 71.96500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 71.965 ENERGY OUT = 70.415(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.523 ENERGY OUT = 72.083(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.08300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.083 ENERGY OUT = 70.535(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.623 ENERGY OUT = 72.201(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.20100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.201 ENERGY OUT = 70.655(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.723 ENERGY OUT = 72.320(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.32000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.320 ENERGY OUT = 70.776(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.823 ENERGY OUT = 72.438(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.43800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.438 ENERGY OUT = 70.896(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 88.923 ENERGY OUT = 72.556(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.55600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.556 ENERGY OUT = 71.016(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.023 ENERGY OUT = 72.674(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.67400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.674 ENERGY OUT = 71.136(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.123 ENERGY OUT = 72.792(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.79200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.792 ENERGY OUT = 71.257(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.223 ENERGY OUT = 72.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 72.91000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 72.910 ENERGY OUT = 71.377(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.323 ENERGY OUT = 73.028(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.02800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.028 ENERGY OUT = 71.497(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.423 ENERGY OUT = 73.146(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.14600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.146 ENERGY OUT = 71.617(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.523 ENERGY OUT = 73.264(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.26400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.264 ENERGY OUT = 71.737(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.623 ENERGY OUT = 73.382(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.38200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.382 ENERGY OUT = 71.857(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.723 ENERGY OUT = 73.500(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.50000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.500 ENERGY OUT = 71.977(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.823 ENERGY OUT = 73.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.61800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.618 ENERGY OUT = 72.097(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 89.923 ENERGY OUT = 73.735(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.73500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.735 ENERGY OUT = 72.216(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.023 ENERGY OUT = 73.853(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.85300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.853 ENERGY OUT = 72.336(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.123 ENERGY OUT = 73.970(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 73.97000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 73.970 ENERGY OUT = 72.455(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.223 ENERGY OUT = 74.088(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.08800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.088 ENERGY OUT = 72.575(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.323 ENERGY OUT = 74.206(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.20600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.206 ENERGY OUT = 72.695(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.423 ENERGY OUT = 74.323(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.323 ENERGY OUT = 72.814(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.523 ENERGY OUT = 74.441(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.44100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.441 ENERGY OUT = 72.934(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.623 ENERGY OUT = 74.558(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.55800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.558 ENERGY OUT = 73.053(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.723 ENERGY OUT = 74.675(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.67500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.675 ENERGY OUT = 73.172(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.823 ENERGY OUT = 74.792(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.79200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.792 ENERGY OUT = 73.291(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 90.923 ENERGY OUT = 74.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 74.91000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 74.910 ENERGY OUT = 73.411(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.023 ENERGY OUT = 75.027(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.02700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.027 ENERGY OUT = 73.530(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.123 ENERGY OUT = 75.144(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.14400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.144 ENERGY OUT = 73.649(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.223 ENERGY OUT = 75.261(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.26100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.261 ENERGY OUT = 73.768(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.323 ENERGY OUT = 75.378(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.37800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.378 ENERGY OUT = 73.887(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.423 ENERGY OUT = 75.496(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.49600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.496 ENERGY OUT = 74.006(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.523 ENERGY OUT = 75.613(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.61300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.613 ENERGY OUT = 74.125(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.623 ENERGY OUT = 75.729(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.72900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.729 ENERGY OUT = 74.243(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.723 ENERGY OUT = 75.846(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.84600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.846 ENERGY OUT = 74.362(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.823 ENERGY OUT = 75.963(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 75.96300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 75.963 ENERGY OUT = 74.481(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 91.923 ENERGY OUT = 76.080(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.08000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.080 ENERGY OUT = 74.600(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.023 ENERGY OUT = 76.197(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.19700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.197 ENERGY OUT = 74.719(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.123 ENERGY OUT = 76.314(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.31400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.314 ENERGY OUT = 74.838(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.223 ENERGY OUT = 76.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.43000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.430 ENERGY OUT = 74.956(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.323 ENERGY OUT = 76.547(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.54700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.547 ENERGY OUT = 75.075(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.423 ENERGY OUT = 76.663(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.66300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.663 ENERGY OUT = 75.192(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.523 ENERGY OUT = 76.780(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.78000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.780 ENERGY OUT = 75.311(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.623 ENERGY OUT = 76.897(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 76.89700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 76.897 ENERGY OUT = 75.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.723 ENERGY OUT = 77.013(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.01300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.013 ENERGY OUT = 75.548(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.823 ENERGY OUT = 77.130(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.13000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.130 ENERGY OUT = 75.667(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 92.923 ENERGY OUT = 77.246(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.24600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.246 ENERGY OUT = 75.785(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.023 ENERGY OUT = 77.362(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.36200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.362 ENERGY OUT = 75.902(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.123 ENERGY OUT = 77.479(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.47900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.479 ENERGY OUT = 76.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.223 ENERGY OUT = 77.595(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.59500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.595 ENERGY OUT = 76.139(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.323 ENERGY OUT = 77.711(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.71100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.711 ENERGY OUT = 76.257(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.423 ENERGY OUT = 77.828(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.82800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.828 ENERGY OUT = 76.376(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.523 ENERGY OUT = 77.944(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 77.94400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 77.944 ENERGY OUT = 76.494(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.623 ENERGY OUT = 78.060(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.06000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.060 ENERGY OUT = 76.611(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.723 ENERGY OUT = 78.176(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.17600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.176 ENERGY OUT = 76.729(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.823 ENERGY OUT = 78.292(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.29200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.292 ENERGY OUT = 76.847(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 93.923 ENERGY OUT = 78.408(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.40800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.408 ENERGY OUT = 76.965(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.023 ENERGY OUT = 78.524(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.52400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.524 ENERGY OUT = 77.083(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.123 ENERGY OUT = 78.640(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.64000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.640 ENERGY OUT = 77.200(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.223 ENERGY OUT = 78.756(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.75600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.756 ENERGY OUT = 77.318(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.323 ENERGY OUT = 78.872(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.87200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.872 ENERGY OUT = 77.436(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.423 ENERGY OUT = 78.988(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 78.98800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 78.988 ENERGY OUT = 77.554(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.523 ENERGY OUT = 79.103(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.10300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.103 ENERGY OUT = 77.670(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.623 ENERGY OUT = 79.219(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.21900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.219 ENERGY OUT = 77.788(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.723 ENERGY OUT = 79.335(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.33500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.335 ENERGY OUT = 77.906(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.823 ENERGY OUT = 79.451(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.45100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.451 ENERGY OUT = 78.024(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 94.923 ENERGY OUT = 79.566(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.56600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.566 ENERGY OUT = 78.140(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.023 ENERGY OUT = 79.682(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.68200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.682 ENERGY OUT = 78.258(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.123 ENERGY OUT = 79.797(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.79700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.797 ENERGY OUT = 78.375(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.223 ENERGY OUT = 79.913(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 79.91300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 79.913 ENERGY OUT = 78.492(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.323 ENERGY OUT = 80.028(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.02800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.028 ENERGY OUT = 78.609(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.423 ENERGY OUT = 80.144(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.14400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.144 ENERGY OUT = 78.727(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.523 ENERGY OUT = 80.259(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.25900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.259 ENERGY OUT = 78.843(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.623 ENERGY OUT = 80.375(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.37500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.375 ENERGY OUT = 78.961(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.723 ENERGY OUT = 80.490(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.49000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.490 ENERGY OUT = 79.078(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.823 ENERGY OUT = 80.605(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.60500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.605 ENERGY OUT = 79.195(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 95.923 ENERGY OUT = 80.721(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.72100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.721 ENERGY OUT = 79.312(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.023 ENERGY OUT = 80.836(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.83600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.836 ENERGY OUT = 79.429(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.123 ENERGY OUT = 80.951(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 80.95100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 80.951 ENERGY OUT = 79.546(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.223 ENERGY OUT = 81.066(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.06600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.066 ENERGY OUT = 79.662(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.323 ENERGY OUT = 81.181(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.18100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.181 ENERGY OUT = 79.779(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.423 ENERGY OUT = 81.296(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.29600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.296 ENERGY OUT = 79.896(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.523 ENERGY OUT = 81.411(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.41100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.411 ENERGY OUT = 80.012(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.623 ENERGY OUT = 81.527(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.52700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.527 ENERGY OUT = 80.130(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.723 ENERGY OUT = 81.642(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.64200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.642 ENERGY OUT = 80.247(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.823 ENERGY OUT = 81.756(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.75600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.756 ENERGY OUT = 80.362(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 96.923 ENERGY OUT = 81.871(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.87100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.871 ENERGY OUT = 80.479(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.023 ENERGY OUT = 81.986(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 81.98600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 81.986 ENERGY OUT = 80.595(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.123 ENERGY OUT = 82.101(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.10100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.101 ENERGY OUT = 80.712(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.223 ENERGY OUT = 82.216(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.21600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.216 ENERGY OUT = 80.829(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.323 ENERGY OUT = 82.331(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.33100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.331 ENERGY OUT = 80.945(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.423 ENERGY OUT = 82.445(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.44500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.445 ENERGY OUT = 81.061(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.523 ENERGY OUT = 82.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.56000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.560 ENERGY OUT = 81.177(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.623 ENERGY OUT = 82.675(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.67500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.675 ENERGY OUT = 81.294(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.723 ENERGY OUT = 82.790(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.79000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.790 ENERGY OUT = 81.411(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.823 ENERGY OUT = 82.904(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 82.90400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 82.904 ENERGY OUT = 81.526(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 97.923 ENERGY OUT = 83.019(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.01900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.019 ENERGY OUT = 81.643(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.023 ENERGY OUT = 83.133(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.13300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.133 ENERGY OUT = 81.758(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.123 ENERGY OUT = 83.248(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.24800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.248 ENERGY OUT = 81.875(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.223 ENERGY OUT = 83.362(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.36200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.362 ENERGY OUT = 81.991(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.323 ENERGY OUT = 83.477(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.47700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.477 ENERGY OUT = 82.107(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.423 ENERGY OUT = 83.591(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.59100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.591 ENERGY OUT = 82.223(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.523 ENERGY OUT = 83.706(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.70600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.706 ENERGY OUT = 82.339(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.623 ENERGY OUT = 83.820(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.82000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.820 ENERGY OUT = 82.455(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.723 ENERGY OUT = 83.934(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 83.93400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 83.934 ENERGY OUT = 82.570(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.823 ENERGY OUT = 84.049(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.04900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.049 ENERGY OUT = 82.687(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 98.923 ENERGY OUT = 84.163(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.16300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.163 ENERGY OUT = 82.802(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.023 ENERGY OUT = 84.277(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.27700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.277 ENERGY OUT = 82.918(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.123 ENERGY OUT = 84.391(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.39100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.391 ENERGY OUT = 83.033(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.223 ENERGY OUT = 84.505(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.50500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.505 ENERGY OUT = 83.149(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.323 ENERGY OUT = 84.620(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.62000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.620 ENERGY OUT = 83.266(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.423 ENERGY OUT = 84.734(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.73400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.734 ENERGY OUT = 83.381(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.523 ENERGY OUT = 84.848(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.84800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.848 ENERGY OUT = 83.497(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.623 ENERGY OUT = 84.962(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 84.96200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 84.962 ENERGY OUT = 83.612(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.723 ENERGY OUT = 85.076(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.07600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 85.076 ENERGY OUT = 83.728(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.823 ENERGY OUT = 85.190(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.19000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 85.190 ENERGY OUT = 83.843(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 99.923 ENERGY OUT = 85.304(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.30400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 85.304 ENERGY OUT = 83.959(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.023 ENERGY OUT = 85.418(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.41800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 85.418 ENERGY OUT = 84.074(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.123 ENERGY OUT = 85.531(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.53100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 85.531 ENERGY OUT = 84.189(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.223 ENERGY OUT = 85.645(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.64500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 128 STEPS ENERGY IN = 85.645 ENERGY OUT = 84.304(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.323 ENERGY OUT = 85.759(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.75900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 85.759 ENERGY OUT = 84.420(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.423 ENERGY OUT = 85.873(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.87300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 85.873 ENERGY OUT = 84.535(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.523 ENERGY OUT = 85.987(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 85.98700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 85.987 ENERGY OUT = 84.651(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.623 ENERGY OUT = 86.100(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.10000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.100 ENERGY OUT = 84.765(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.723 ENERGY OUT = 86.214(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.21400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.214 ENERGY OUT = 84.881(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.823 ENERGY OUT = 86.328(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.32800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.328 ENERGY OUT = 84.996(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 100.923 ENERGY OUT = 86.441(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.44100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.441 ENERGY OUT = 85.110(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.023 ENERGY OUT = 86.555(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.55500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.555 ENERGY OUT = 85.226(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.123 ENERGY OUT = 86.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.66900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.669 ENERGY OUT = 85.341(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.223 ENERGY OUT = 86.782(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.78200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.782 ENERGY OUT = 85.456(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.323 ENERGY OUT = 86.896(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 86.89600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 86.896 ENERGY OUT = 85.571(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.423 ENERGY OUT = 87.009(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.00900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.009 ENERGY OUT = 85.686(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.523 ENERGY OUT = 87.123(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.123 ENERGY OUT = 85.801(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.623 ENERGY OUT = 87.236(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.23600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.236 ENERGY OUT = 85.916(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.723 ENERGY OUT = 87.350(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.35000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.350 ENERGY OUT = 86.031(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.823 ENERGY OUT = 87.463(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.46300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.463 ENERGY OUT = 86.145(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 101.923 ENERGY OUT = 87.576(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.57600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.576 ENERGY OUT = 86.260(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.023 ENERGY OUT = 87.690(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.69000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.690 ENERGY OUT = 86.375(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.123 ENERGY OUT = 87.803(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.80300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.803 ENERGY OUT = 86.490(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.223 ENERGY OUT = 87.916(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 87.91600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 87.916 ENERGY OUT = 86.604(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.323 ENERGY OUT = 88.029(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.02900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.029 ENERGY OUT = 86.719(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.423 ENERGY OUT = 88.143(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.14300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.143 ENERGY OUT = 86.834(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.523 ENERGY OUT = 88.256(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.25600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.256 ENERGY OUT = 86.948(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.623 ENERGY OUT = 88.369(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.36900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.369 ENERGY OUT = 87.063(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.723 ENERGY OUT = 88.482(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.48200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.482 ENERGY OUT = 87.177(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.823 ENERGY OUT = 88.595(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.59500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.595 ENERGY OUT = 87.291(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 102.923 ENERGY OUT = 88.708(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.70800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.708 ENERGY OUT = 87.406(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.023 ENERGY OUT = 88.821(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.82100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.821 ENERGY OUT = 87.520(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.123 ENERGY OUT = 88.934(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 88.93400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 88.934 ENERGY OUT = 87.635(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.223 ENERGY OUT = 89.047(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.04700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.047 ENERGY OUT = 87.749(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.323 ENERGY OUT = 89.160(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.16000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.160 ENERGY OUT = 87.863(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.423 ENERGY OUT = 89.273(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.27300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.273 ENERGY OUT = 87.978(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.523 ENERGY OUT = 89.386(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.38600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.386 ENERGY OUT = 88.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.623 ENERGY OUT = 89.499(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.49900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.499 ENERGY OUT = 88.207(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.723 ENERGY OUT = 89.612(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.61200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.612 ENERGY OUT = 88.321(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.823 ENERGY OUT = 89.725(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.72500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.725 ENERGY OUT = 88.435(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 103.923 ENERGY OUT = 89.837(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.83700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.837 ENERGY OUT = 88.549(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.023 ENERGY OUT = 89.950(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 89.95000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 89.950 ENERGY OUT = 88.663(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.123 ENERGY OUT = 90.063(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.06300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.063 ENERGY OUT = 88.777(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.223 ENERGY OUT = 90.176(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.17600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.176 ENERGY OUT = 88.892(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.323 ENERGY OUT = 90.288(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.28800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.288 ENERGY OUT = 89.005(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.423 ENERGY OUT = 90.401(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.40100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.401 ENERGY OUT = 89.119(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.523 ENERGY OUT = 90.514(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.51400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.514 ENERGY OUT = 89.234(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.623 ENERGY OUT = 90.626(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.62600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.626 ENERGY OUT = 89.347(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.723 ENERGY OUT = 90.739(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.73900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.739 ENERGY OUT = 89.461(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.823 ENERGY OUT = 90.851(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.85100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.851 ENERGY OUT = 89.575(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 104.923 ENERGY OUT = 90.964(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 90.96400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 90.964 ENERGY OUT = 89.689(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.023 ENERGY OUT = 91.076(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.07600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.076 ENERGY OUT = 89.802(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.123 ENERGY OUT = 91.189(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.18900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.189 ENERGY OUT = 89.917(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.223 ENERGY OUT = 91.301(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.30100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.301 ENERGY OUT = 90.030(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.323 ENERGY OUT = 91.414(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.41400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.414 ENERGY OUT = 90.144(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.423 ENERGY OUT = 91.526(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.52600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.526 ENERGY OUT = 90.257(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.523 ENERGY OUT = 91.638(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.63800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.638 ENERGY OUT = 90.371(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.623 ENERGY OUT = 91.751(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.75100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.751 ENERGY OUT = 90.485(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.723 ENERGY OUT = 91.863(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.86300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.863 ENERGY OUT = 90.598(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN-1024 STEPS ENERGY IN = 105.823 ENERGY OUT = 91.975(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 91.97500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 91.975 ENERGY OUT = 90.712(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 105.923 ENERGY OUT = 92.089(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.08900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.089 ENERGY OUT = 90.827(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.023 ENERGY OUT = 92.201(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.20100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.201 ENERGY OUT = 90.940(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.123 ENERGY OUT = 92.313(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.31300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.313 ENERGY OUT = 91.053(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.223 ENERGY OUT = 92.425(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.42500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.425 ENERGY OUT = 91.167(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.323 ENERGY OUT = 92.537(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.53700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.537 ENERGY OUT = 91.280(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.423 ENERGY OUT = 92.650(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.65000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.650 ENERGY OUT = 91.394(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.523 ENERGY OUT = 92.762(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.76200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.762 ENERGY OUT = 91.508(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.623 ENERGY OUT = 92.874(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.87400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.874 ENERGY OUT = 91.621(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.723 ENERGY OUT = 92.986(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 92.98600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 92.986 ENERGY OUT = 91.734(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.823 ENERGY OUT = 93.098(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.09800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.098 ENERGY OUT = 91.847(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 106.923 ENERGY OUT = 93.210(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.21000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.210 ENERGY OUT = 91.961(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.023 ENERGY OUT = 93.322(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.32200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.322 ENERGY OUT = 92.074(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.123 ENERGY OUT = 93.434(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.43400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.434 ENERGY OUT = 92.187(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.223 ENERGY OUT = 93.546(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.54600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.546 ENERGY OUT = 92.300(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.323 ENERGY OUT = 93.658(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.65800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.658 ENERGY OUT = 92.414(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.423 ENERGY OUT = 93.770(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.77000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.770 ENERGY OUT = 92.527(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.523 ENERGY OUT = 93.882(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.88200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.882 ENERGY OUT = 92.640(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.623 ENERGY OUT = 93.993(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 93.99300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 93.993 ENERGY OUT = 92.752(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.723 ENERGY OUT = 94.105(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.10500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.105 ENERGY OUT = 92.866(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.823 ENERGY OUT = 94.217(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.21700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.217 ENERGY OUT = 92.979(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 107.923 ENERGY OUT = 94.329(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.32900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.329 ENERGY OUT = 93.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.023 ENERGY OUT = 94.441(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.44100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.441 ENERGY OUT = 93.205(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.123 ENERGY OUT = 94.552(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.55200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.552 ENERGY OUT = 93.317(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.223 ENERGY OUT = 94.664(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.66400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.664 ENERGY OUT = 93.431(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.323 ENERGY OUT = 94.776(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.77600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.776 ENERGY OUT = 93.544(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.423 ENERGY OUT = 94.887(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.88700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.887 ENERGY OUT = 93.656(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.523 ENERGY OUT = 94.999(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 94.99900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 94.999 ENERGY OUT = 93.769(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.623 ENERGY OUT = 95.111(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.11100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.111 ENERGY OUT = 93.882(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.723 ENERGY OUT = 95.222(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.22200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.222 ENERGY OUT = 93.995(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.823 ENERGY OUT = 95.334(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.33400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.334 ENERGY OUT = 94.108(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 108.923 ENERGY OUT = 95.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.44600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.446 ENERGY OUT = 94.221(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.023 ENERGY OUT = 95.557(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.55700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.557 ENERGY OUT = 94.333(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.123 ENERGY OUT = 95.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.66900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.669 ENERGY OUT = 94.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.223 ENERGY OUT = 95.780(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.78000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.780 ENERGY OUT = 94.559(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.323 ENERGY OUT = 95.891(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 95.89100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 95.891 ENERGY OUT = 94.671(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.423 ENERGY OUT = 96.003(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.00300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.003 ENERGY OUT = 94.784(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.523 ENERGY OUT = 96.114(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.11400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.114 ENERGY OUT = 94.896(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.623 ENERGY OUT = 96.226(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.22600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.226 ENERGY OUT = 95.009(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.723 ENERGY OUT = 96.337(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.33700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.337 ENERGY OUT = 95.122(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.823 ENERGY OUT = 96.448(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.44800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.448 ENERGY OUT = 95.234(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 109.923 ENERGY OUT = 96.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.56000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.560 ENERGY OUT = 95.347(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.023 ENERGY OUT = 96.671(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.67100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.671 ENERGY OUT = 95.459(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.123 ENERGY OUT = 96.782(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.78200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.782 ENERGY OUT = 95.571(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.223 ENERGY OUT = 96.894(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 96.89400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 96.894 ENERGY OUT = 95.684(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.323 ENERGY OUT = 97.005(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.00500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.005 ENERGY OUT = 95.797(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.423 ENERGY OUT = 97.116(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.11600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.116 ENERGY OUT = 95.909(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.523 ENERGY OUT = 97.227(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.22700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.227 ENERGY OUT = 96.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.623 ENERGY OUT = 97.339(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.33900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.339 ENERGY OUT = 96.134(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.723 ENERGY OUT = 97.450(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.45000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.450 ENERGY OUT = 96.246(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.823 ENERGY OUT = 97.561(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.56100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.561 ENERGY OUT = 96.358(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 110.923 ENERGY OUT = 97.672(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.67200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.672 ENERGY OUT = 96.470(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.023 ENERGY OUT = 97.783(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.78300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.783 ENERGY OUT = 96.583(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.123 ENERGY OUT = 97.894(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 97.89400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 97.894 ENERGY OUT = 96.695(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.223 ENERGY OUT = 98.005(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.00500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.005 ENERGY OUT = 96.807(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.323 ENERGY OUT = 98.116(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.11600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.116 ENERGY OUT = 96.919(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.423 ENERGY OUT = 98.227(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.22700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.227 ENERGY OUT = 97.031(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.523 ENERGY OUT = 98.338(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.33800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.338 ENERGY OUT = 97.143(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.623 ENERGY OUT = 98.449(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.44900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.449 ENERGY OUT = 97.255(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.723 ENERGY OUT = 98.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.56000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.560 ENERGY OUT = 97.367(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.823 ENERGY OUT = 98.671(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.67100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.671 ENERGY OUT = 97.480(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 111.923 ENERGY OUT = 98.782(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.78200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.782 ENERGY OUT = 97.592(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.023 ENERGY OUT = 98.893(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 98.89300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 98.893 ENERGY OUT = 97.704(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.123 ENERGY OUT = 99.004(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.00400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.004 ENERGY OUT = 97.816(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.223 ENERGY OUT = 99.115(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.11500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.115 ENERGY OUT = 97.928(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.323 ENERGY OUT = 99.225(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.22500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.225 ENERGY OUT = 98.039(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.423 ENERGY OUT = 99.336(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.33600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.336 ENERGY OUT = 98.151(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.523 ENERGY OUT = 99.447(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.44700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.447 ENERGY OUT = 98.263(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.623 ENERGY OUT = 99.558(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.55800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.558 ENERGY OUT = 98.375(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.723 ENERGY OUT = 99.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.66900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.669 ENERGY OUT = 98.488(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.823 ENERGY OUT = 99.779(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.77900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.779 ENERGY OUT = 98.599(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 112.923 ENERGY OUT = 99.890(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 99.89000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 99.890 ENERGY OUT = 98.711(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.023 ENERGY OUT = 100.001(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.00100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.001 ENERGY OUT = 98.823(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.123 ENERGY OUT = 100.111(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.11100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.111 ENERGY OUT = 98.934(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.223 ENERGY OUT = 100.222(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.22200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.222 ENERGY OUT = 99.046(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.323 ENERGY OUT = 100.333(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.33300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.333 ENERGY OUT = 99.158(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.423 ENERGY OUT = 100.443(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.44300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.443 ENERGY OUT = 99.269(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.523 ENERGY OUT = 100.554(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.55400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.554 ENERGY OUT = 99.381(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.623 ENERGY OUT = 100.664(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.66400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.664 ENERGY OUT = 99.492(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.723 ENERGY OUT = 100.775(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.77500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.775 ENERGY OUT = 99.604(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.823 ENERGY OUT = 100.885(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.88500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.885 ENERGY OUT = 99.715(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 113.923 ENERGY OUT = 100.996(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 100.99600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 100.996 ENERGY OUT = 99.828(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.023 ENERGY OUT = 101.106(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.10600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.106 ENERGY OUT = 99.939(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.123 ENERGY OUT = 101.217(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.21700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.217 ENERGY OUT = 100.051(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.223 ENERGY OUT = 101.327(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.32700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.327 ENERGY OUT = 100.162(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.323 ENERGY OUT = 101.438(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.43800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.438 ENERGY OUT = 100.274(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.423 ENERGY OUT = 101.548(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.54800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.548 ENERGY OUT = 100.385(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.523 ENERGY OUT = 101.659(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.65900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.659 ENERGY OUT = 100.497(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.623 ENERGY OUT = 101.769(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.76900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.769 ENERGY OUT = 100.608(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.723 ENERGY OUT = 101.879(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.87900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.879 ENERGY OUT = 100.719(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.823 ENERGY OUT = 101.990(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 101.99000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 101.990 ENERGY OUT = 100.831(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 114.923 ENERGY OUT = 102.100(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.10000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.100 ENERGY OUT = 100.942(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.023 ENERGY OUT = 102.210(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.21000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.210 ENERGY OUT = 101.053(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.123 ENERGY OUT = 102.320(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.32000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.320 ENERGY OUT = 101.164(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.223 ENERGY OUT = 102.431(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.43100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.431 ENERGY OUT = 101.276(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.323 ENERGY OUT = 102.541(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.54100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.541 ENERGY OUT = 101.387(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.423 ENERGY OUT = 102.651(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.65100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.651 ENERGY OUT = 101.498(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.523 ENERGY OUT = 102.761(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.76100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.761 ENERGY OUT = 101.609(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.623 ENERGY OUT = 102.872(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.87200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.872 ENERGY OUT = 101.721(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.723 ENERGY OUT = 102.982(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 102.98200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 102.982 ENERGY OUT = 101.832(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.823 ENERGY OUT = 103.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.09200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.092 ENERGY OUT = 101.943(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 115.923 ENERGY OUT = 103.202(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.20200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.202 ENERGY OUT = 102.054(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.023 ENERGY OUT = 103.312(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.31200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.312 ENERGY OUT = 102.165(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.123 ENERGY OUT = 103.422(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.42200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.422 ENERGY OUT = 102.277(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.223 ENERGY OUT = 103.532(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.53200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.532 ENERGY OUT = 102.388(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.323 ENERGY OUT = 103.642(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.64200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.642 ENERGY OUT = 102.499(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.423 ENERGY OUT = 103.752(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.75200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.752 ENERGY OUT = 102.610(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.523 ENERGY OUT = 103.862(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.86200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.862 ENERGY OUT = 102.721(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.623 ENERGY OUT = 103.972(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 103.97200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 103.972 ENERGY OUT = 102.832(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.723 ENERGY OUT = 104.082(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.08200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.082 ENERGY OUT = 102.943(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.823 ENERGY OUT = 104.192(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.19200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.192 ENERGY OUT = 103.054(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 116.923 ENERGY OUT = 104.302(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.30200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.302 ENERGY OUT = 103.165(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.023 ENERGY OUT = 104.412(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.41200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.412 ENERGY OUT = 103.276(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.123 ENERGY OUT = 104.522(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.52200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.522 ENERGY OUT = 103.387(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.223 ENERGY OUT = 104.632(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.63200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.632 ENERGY OUT = 103.498(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.323 ENERGY OUT = 104.742(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.74200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.742 ENERGY OUT = 103.609(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.423 ENERGY OUT = 104.852(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.85200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.852 ENERGY OUT = 103.720(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.523 ENERGY OUT = 104.962(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 104.96200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 104.962 ENERGY OUT = 103.831(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.623 ENERGY OUT = 105.072(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.07200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.072 ENERGY OUT = 103.942(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.723 ENERGY OUT = 105.181(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.18100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.181 ENERGY OUT = 104.052(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.823 ENERGY OUT = 105.291(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.29100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.291 ENERGY OUT = 104.163(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 117.923 ENERGY OUT = 105.401(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.40100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.401 ENERGY OUT = 104.274(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.023 ENERGY OUT = 105.511(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.51100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.511 ENERGY OUT = 104.385(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.123 ENERGY OUT = 105.620(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.62000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.620 ENERGY OUT = 104.494(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.223 ENERGY OUT = 105.730(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.73000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.730 ENERGY OUT = 104.605(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.323 ENERGY OUT = 105.840(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.84000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.840 ENERGY OUT = 104.716(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.423 ENERGY OUT = 105.950(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 105.95000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 105.950 ENERGY OUT = 104.827(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.523 ENERGY OUT = 106.059(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.05900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.059 ENERGY OUT = 104.937(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.623 ENERGY OUT = 106.169(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.16900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.169 ENERGY OUT = 105.048(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.723 ENERGY OUT = 106.278(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.27800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.278 ENERGY OUT = 105.158(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.823 ENERGY OUT = 106.388(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.38800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.388 ENERGY OUT = 105.269(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 118.923 ENERGY OUT = 106.498(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.49800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.498 ENERGY OUT = 105.380(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.023 ENERGY OUT = 106.607(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.60700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.607 ENERGY OUT = 105.490(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.123 ENERGY OUT = 106.717(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.71700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.717 ENERGY OUT = 105.601(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.223 ENERGY OUT = 106.826(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.82600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.826 ENERGY OUT = 105.711(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.323 ENERGY OUT = 106.936(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 106.93600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 106.936 ENERGY OUT = 105.822(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.423 ENERGY OUT = 107.046(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.04600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.046 ENERGY OUT = 105.933(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.523 ENERGY OUT = 107.155(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.15500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.155 ENERGY OUT = 106.043(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.623 ENERGY OUT = 107.264(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.26400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.264 ENERGY OUT = 106.153(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.723 ENERGY OUT = 107.374(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.37400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.374 ENERGY OUT = 106.264(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.823 ENERGY OUT = 107.483(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.48300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.483 ENERGY OUT = 106.374(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 119.923 ENERGY OUT = 107.593(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.59300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.593 ENERGY OUT = 106.485(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.023 ENERGY OUT = 107.702(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.70200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.702 ENERGY OUT = 106.595(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.123 ENERGY OUT = 107.812(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.81200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.812 ENERGY OUT = 106.706(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.223 ENERGY OUT = 107.921(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 107.92100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 107.921 ENERGY OUT = 106.816(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.323 ENERGY OUT = 108.030(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.03000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.030 ENERGY OUT = 106.926(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.423 ENERGY OUT = 108.140(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.14000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.140 ENERGY OUT = 107.036(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.523 ENERGY OUT = 108.249(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.24900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.249 ENERGY OUT = 107.146(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.623 ENERGY OUT = 108.358(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.35800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.358 ENERGY OUT = 107.256(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.723 ENERGY OUT = 108.468(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.46800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.468 ENERGY OUT = 107.367(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.823 ENERGY OUT = 108.577(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.57700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.577 ENERGY OUT = 107.477(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 120.923 ENERGY OUT = 108.686(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.68600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.686 ENERGY OUT = 107.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.023 ENERGY OUT = 108.795(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.79500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.795 ENERGY OUT = 107.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.123 ENERGY OUT = 108.905(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 108.90500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 108.905 ENERGY OUT = 107.808(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.223 ENERGY OUT = 109.014(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.01400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.014 ENERGY OUT = 107.918(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.323 ENERGY OUT = 109.123(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.123 ENERGY OUT = 108.028(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.423 ENERGY OUT = 109.232(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.23200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.232 ENERGY OUT = 108.138(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.523 ENERGY OUT = 109.342(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.34200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.342 ENERGY OUT = 108.249(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.623 ENERGY OUT = 109.451(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.45100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.451 ENERGY OUT = 108.359(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.723 ENERGY OUT = 109.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.56000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.560 ENERGY OUT = 108.468(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.823 ENERGY OUT = 109.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.66900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.669 ENERGY OUT = 108.578(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 121.923 ENERGY OUT = 109.778(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.77800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.778 ENERGY OUT = 108.688(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.023 ENERGY OUT = 109.887(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.88700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.887 ENERGY OUT = 108.798(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.123 ENERGY OUT = 109.996(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 109.99600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 109.996 ENERGY OUT = 108.908(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.223 ENERGY OUT = 110.105(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.10500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.105 ENERGY OUT = 109.018(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.323 ENERGY OUT = 110.214(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.21400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.214 ENERGY OUT = 109.128(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.423 ENERGY OUT = 110.324(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.32400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.324 ENERGY OUT = 109.239(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.523 ENERGY OUT = 110.433(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.43300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.433 ENERGY OUT = 109.349(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.623 ENERGY OUT = 110.542(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.54200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.542 ENERGY OUT = 109.459(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.723 ENERGY OUT = 110.651(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.65100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.651 ENERGY OUT = 109.568(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.823 ENERGY OUT = 110.759(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.75900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.759 ENERGY OUT = 109.677(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 122.923 ENERGY OUT = 110.869(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.86900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.869 ENERGY OUT = 109.788(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.023 ENERGY OUT = 110.977(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 110.97700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 110.977 ENERGY OUT = 109.897(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.123 ENERGY OUT = 111.086(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.08600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.086 ENERGY OUT = 110.007(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.223 ENERGY OUT = 111.195(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.19500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.195 ENERGY OUT = 110.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.323 ENERGY OUT = 111.304(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.30400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.304 ENERGY OUT = 110.227(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.423 ENERGY OUT = 111.413(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.41300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.413 ENERGY OUT = 110.337(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.523 ENERGY OUT = 111.522(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.52200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.522 ENERGY OUT = 110.447(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.623 ENERGY OUT = 111.631(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.63100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.631 ENERGY OUT = 110.556(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.723 ENERGY OUT = 111.740(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.74000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.740 ENERGY OUT = 110.666(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.823 ENERGY OUT = 111.849(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.84900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.849 ENERGY OUT = 110.776(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 123.923 ENERGY OUT = 111.957(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 111.95700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 111.957 ENERGY OUT = 110.885(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.023 ENERGY OUT = 112.066(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.06600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.066 ENERGY OUT = 110.995(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.123 ENERGY OUT = 112.175(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.17500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.175 ENERGY OUT = 111.105(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.223 ENERGY OUT = 112.284(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.28400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.284 ENERGY OUT = 111.215(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.323 ENERGY OUT = 112.392(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.39200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.392 ENERGY OUT = 111.324(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.423 ENERGY OUT = 112.501(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.50100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.501 ENERGY OUT = 111.433(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.523 ENERGY OUT = 112.610(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.61000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.610 ENERGY OUT = 111.543(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.623 ENERGY OUT = 112.719(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.71900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.719 ENERGY OUT = 111.653(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.723 ENERGY OUT = 112.827(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.82700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.827 ENERGY OUT = 111.762(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.823 ENERGY OUT = 112.936(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 112.93600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 112.936 ENERGY OUT = 111.872(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 124.923 ENERGY OUT = 113.045(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.04500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.045 ENERGY OUT = 111.982(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.023 ENERGY OUT = 113.153(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.15300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.153 ENERGY OUT = 112.091(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.123 ENERGY OUT = 113.262(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.26200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.262 ENERGY OUT = 112.200(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.223 ENERGY OUT = 113.371(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.37100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.371 ENERGY OUT = 112.310(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.323 ENERGY OUT = 113.479(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.47900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.479 ENERGY OUT = 112.419(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.423 ENERGY OUT = 113.588(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.58800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.588 ENERGY OUT = 112.529(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.523 ENERGY OUT = 113.696(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.69600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.696 ENERGY OUT = 112.638(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.623 ENERGY OUT = 113.805(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.80500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.805 ENERGY OUT = 112.748(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.723 ENERGY OUT = 113.914(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 113.91400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 113.914 ENERGY OUT = 112.857(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.823 ENERGY OUT = 114.022(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.02200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.022 ENERGY OUT = 112.966(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 125.923 ENERGY OUT = 114.131(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.13100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.131 ENERGY OUT = 113.076(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.023 ENERGY OUT = 114.239(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.23900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.239 ENERGY OUT = 113.185(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.123 ENERGY OUT = 114.348(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.34800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.348 ENERGY OUT = 113.295(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.223 ENERGY OUT = 114.456(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.45600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.456 ENERGY OUT = 113.404(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.323 ENERGY OUT = 114.565(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.56500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.565 ENERGY OUT = 113.514(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.423 ENERGY OUT = 114.673(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.67300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.673 ENERGY OUT = 113.622(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.523 ENERGY OUT = 114.781(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.78100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.781 ENERGY OUT = 113.731(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.623 ENERGY OUT = 114.890(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.89000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.890 ENERGY OUT = 113.841(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.723 ENERGY OUT = 114.998(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 114.99800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 114.998 ENERGY OUT = 113.950(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.823 ENERGY OUT = 115.107(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.10700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.107 ENERGY OUT = 114.060(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 126.923 ENERGY OUT = 115.215(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.21500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.215 ENERGY OUT = 114.168(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.02300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.023 ENERGY OUT = 115.324(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.32400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.324 ENERGY OUT = 114.278(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.123 ENERGY OUT = 115.432(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.43200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.432 ENERGY OUT = 114.387(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.22300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.223 ENERGY OUT = 115.540(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.54000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.540 ENERGY OUT = 114.496(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.323 ENERGY OUT = 115.649(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.64900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.649 ENERGY OUT = 114.606(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.423 ENERGY OUT = 115.757(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.75700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.757 ENERGY OUT = 114.715(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.523 ENERGY OUT = 115.865(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.86500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.865 ENERGY OUT = 114.823(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.623 ENERGY OUT = 115.974(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 115.97400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 115.974 ENERGY OUT = 114.933(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.72300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.723 ENERGY OUT = 116.082(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.08200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.082 ENERGY OUT = 115.042(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.823 ENERGY OUT = 116.190(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.19000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.190 ENERGY OUT = 115.151(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 127.923 ENERGY OUT = 116.298(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.29800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.298 ENERGY OUT = 115.260(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.023 ENERGY OUT = 116.407(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.40700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.407 ENERGY OUT = 115.369(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.123 ENERGY OUT = 116.515(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.51500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.515 ENERGY OUT = 115.478(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.223 ENERGY OUT = 116.623(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.623 ENERGY OUT = 115.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.323 ENERGY OUT = 116.731(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.73100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.731 ENERGY OUT = 115.696(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.423 ENERGY OUT = 116.840(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.84000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.840 ENERGY OUT = 115.806(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.523 ENERGY OUT = 116.948(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 116.94800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 116.948 ENERGY OUT = 115.914(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.623 ENERGY OUT = 117.056(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.05600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.056 ENERGY OUT = 116.023(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.723 ENERGY OUT = 117.164(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.16400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.164 ENERGY OUT = 116.132(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.823 ENERGY OUT = 117.272(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.27200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.272 ENERGY OUT = 116.241(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 128.923 ENERGY OUT = 117.380(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.38000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.380 ENERGY OUT = 116.350(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.023 ENERGY OUT = 117.488(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.48800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.488 ENERGY OUT = 116.458(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.123 ENERGY OUT = 117.596(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.59600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.596 ENERGY OUT = 116.567(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.223 ENERGY OUT = 117.705(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.70500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.705 ENERGY OUT = 116.677(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.323 ENERGY OUT = 117.813(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.81300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.813 ENERGY OUT = 116.786(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.423 ENERGY OUT = 117.921(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 117.92100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 117.921 ENERGY OUT = 116.895(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.523 ENERGY OUT = 118.029(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.02900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.029 ENERGY OUT = 117.003(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.623 ENERGY OUT = 118.137(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.13700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.137 ENERGY OUT = 117.112(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.723 ENERGY OUT = 118.245(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.24500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.245 ENERGY OUT = 117.221(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.823 ENERGY OUT = 118.353(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.35300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.353 ENERGY OUT = 117.330(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 129.923 ENERGY OUT = 118.461(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.46100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.461 ENERGY OUT = 117.439(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.023 ENERGY OUT = 118.569(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.56900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.569 ENERGY OUT = 117.547(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.123 ENERGY OUT = 118.677(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.67700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.677 ENERGY OUT = 117.656(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.223 ENERGY OUT = 118.785(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.78500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.785 ENERGY OUT = 117.765(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.323 ENERGY OUT = 118.893(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 118.89300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 118.893 ENERGY OUT = 117.874(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.423 ENERGY OUT = 119.001(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.00100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.001 ENERGY OUT = 117.982(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.523 ENERGY OUT = 119.109(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.10900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.109 ENERGY OUT = 118.091(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.623 ENERGY OUT = 119.217(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.21700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.217 ENERGY OUT = 118.200(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.723 ENERGY OUT = 119.324(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.32400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.324 ENERGY OUT = 118.308(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.823 ENERGY OUT = 119.432(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.43200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.432 ENERGY OUT = 118.417(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 130.923 ENERGY OUT = 119.540(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.54000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.540 ENERGY OUT = 118.525(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.023 ENERGY OUT = 119.648(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.64800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.648 ENERGY OUT = 118.634(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.123 ENERGY OUT = 119.756(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.75600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.756 ENERGY OUT = 118.743(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.223 ENERGY OUT = 119.864(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.86400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.864 ENERGY OUT = 118.852(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.323 ENERGY OUT = 119.972(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 119.97200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 119.972 ENERGY OUT = 118.960(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.423 ENERGY OUT = 120.079(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.07900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.079 ENERGY OUT = 119.068(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.523 ENERGY OUT = 120.187(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.18700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.187 ENERGY OUT = 119.177(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.623 ENERGY OUT = 120.295(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.29500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.295 ENERGY OUT = 119.286(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.723 ENERGY OUT = 120.403(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.40300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.403 ENERGY OUT = 119.394(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.823 ENERGY OUT = 120.511(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.51100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.511 ENERGY OUT = 119.503(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 131.923 ENERGY OUT = 120.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.61800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.618 ENERGY OUT = 119.611(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.023 ENERGY OUT = 120.726(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.72600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.726 ENERGY OUT = 119.720(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.123 ENERGY OUT = 120.834(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.83400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.834 ENERGY OUT = 119.828(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.223 ENERGY OUT = 120.942(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 120.94200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 120.942 ENERGY OUT = 119.937(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.323 ENERGY OUT = 121.049(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.04900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.049 ENERGY OUT = 120.045(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.423 ENERGY OUT = 121.157(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.15700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.157 ENERGY OUT = 120.154(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.523 ENERGY OUT = 121.265(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.26500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.265 ENERGY OUT = 120.262(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.623 ENERGY OUT = 121.372(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.37200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.372 ENERGY OUT = 120.370(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.723 ENERGY OUT = 121.480(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.48000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.480 ENERGY OUT = 120.479(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.823 ENERGY OUT = 121.588(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.58800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.588 ENERGY OUT = 120.588(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 132.923 ENERGY OUT = 121.695(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.69500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.695 ENERGY OUT = 120.695(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.023 ENERGY OUT = 121.803(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.80300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.803 ENERGY OUT = 120.804(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.123 ENERGY OUT = 121.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 121.91000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 121.910 ENERGY OUT = 120.912(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.223 ENERGY OUT = 122.018(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.01800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.018 ENERGY OUT = 121.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.323 ENERGY OUT = 122.126(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.12600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.126 ENERGY OUT = 121.129(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.423 ENERGY OUT = 122.233(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.23300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.233 ENERGY OUT = 121.237(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.523 ENERGY OUT = 122.341(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.34100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.341 ENERGY OUT = 121.346(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.623 ENERGY OUT = 122.448(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.44800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.448 ENERGY OUT = 121.454(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.723 ENERGY OUT = 122.556(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.55600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.556 ENERGY OUT = 121.562(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.823 ENERGY OUT = 122.663(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.66300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.663 ENERGY OUT = 121.670(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 133.923 ENERGY OUT = 122.771(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.77100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.771 ENERGY OUT = 121.779(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.023 ENERGY OUT = 122.879(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.87900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.879 ENERGY OUT = 121.887(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.123 ENERGY OUT = 122.986(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 122.98600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 122.986 ENERGY OUT = 121.995(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.223 ENERGY OUT = 123.094(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.09400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.094 ENERGY OUT = 122.104(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.323 ENERGY OUT = 123.201(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.20100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.201 ENERGY OUT = 122.212(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.423 ENERGY OUT = 123.309(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.30900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.309 ENERGY OUT = 122.320(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.523 ENERGY OUT = 123.416(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.41600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.416 ENERGY OUT = 122.428(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.623 ENERGY OUT = 123.523(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.52300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.523 ENERGY OUT = 122.536(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.723 ENERGY OUT = 123.631(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.63100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.631 ENERGY OUT = 122.645(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.823 ENERGY OUT = 123.738(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.73800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.738 ENERGY OUT = 122.752(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 134.923 ENERGY OUT = 123.846(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.84600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.846 ENERGY OUT = 122.861(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.023 ENERGY OUT = 123.953(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 123.95300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 123.953 ENERGY OUT = 122.969(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.123 ENERGY OUT = 124.060(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.06000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.060 ENERGY OUT = 123.076(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.223 ENERGY OUT = 124.168(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.16800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.168 ENERGY OUT = 123.185(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.323 ENERGY OUT = 124.275(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.27500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.275 ENERGY OUT = 123.293(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.423 ENERGY OUT = 124.383(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.38300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.383 ENERGY OUT = 123.402(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.523 ENERGY OUT = 124.490(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.49000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.490 ENERGY OUT = 123.509(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.623 ENERGY OUT = 124.597(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.59700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.597 ENERGY OUT = 123.617(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.723 ENERGY OUT = 124.704(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.70400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.704 ENERGY OUT = 123.725(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.823 ENERGY OUT = 124.812(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.81200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.812 ENERGY OUT = 123.833(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 135.923 ENERGY OUT = 124.919(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 124.91900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 124.919 ENERGY OUT = 123.941(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.023 ENERGY OUT = 125.026(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.02600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.026 ENERGY OUT = 124.049(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.123 ENERGY OUT = 125.134(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.13400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.134 ENERGY OUT = 124.158(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.223 ENERGY OUT = 125.241(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.24100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.241 ENERGY OUT = 124.265(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.323 ENERGY OUT = 125.348(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.34800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.348 ENERGY OUT = 124.373(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.423 ENERGY OUT = 125.456(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.45600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.456 ENERGY OUT = 124.482(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.523 ENERGY OUT = 125.563(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.56300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.563 ENERGY OUT = 124.589(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.623 ENERGY OUT = 125.670(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.67000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.670 ENERGY OUT = 124.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.723 ENERGY OUT = 125.777(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.77700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.777 ENERGY OUT = 124.805(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.823 ENERGY OUT = 125.884(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.88400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.884 ENERGY OUT = 124.912(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 136.923 ENERGY OUT = 125.992(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 125.99200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 125.992 ENERGY OUT = 125.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.023 ENERGY OUT = 126.099(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.09900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 64 STEPS ENERGY IN = 126.099 ENERGY OUT = 125.129(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.123 ENERGY OUT = 126.206(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.20600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.206 ENERGY OUT = 125.237(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.223 ENERGY OUT = 126.313(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.31300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.313 ENERGY OUT = 125.344(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.323 ENERGY OUT = 126.420(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.42000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.420 ENERGY OUT = 125.452(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.423 ENERGY OUT = 126.527(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.52700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.527 ENERGY OUT = 125.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.523 ENERGY OUT = 126.634(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.63400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.634 ENERGY OUT = 125.667(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.623 ENERGY OUT = 126.742(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.74200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.742 ENERGY OUT = 125.776(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.723 ENERGY OUT = 126.849(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.84900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.849 ENERGY OUT = 125.884(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.823 ENERGY OUT = 126.956(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 126.95600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 126.956 ENERGY OUT = 125.991(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 137.923 ENERGY OUT = 127.063(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.06300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.063 ENERGY OUT = 126.099(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.023 ENERGY OUT = 127.170(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.17000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.170 ENERGY OUT = 126.207(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.123 ENERGY OUT = 127.277(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.27700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.277 ENERGY OUT = 126.314(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.223 ENERGY OUT = 127.384(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.38400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.384 ENERGY OUT = 126.422(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.323 ENERGY OUT = 127.491(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.49100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.491 ENERGY OUT = 126.530(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.423 ENERGY OUT = 127.598(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.59800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.598 ENERGY OUT = 126.637(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.523 ENERGY OUT = 127.705(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.70500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.705 ENERGY OUT = 126.745(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.623 ENERGY OUT = 127.812(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.81200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.812 ENERGY OUT = 126.853(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.723 ENERGY OUT = 127.919(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 127.91900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 127.919 ENERGY OUT = 126.960(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.823 ENERGY OUT = 128.026(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.02600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.026 ENERGY OUT = 127.068(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 138.923 ENERGY OUT = 128.133(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.13300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.133 ENERGY OUT = 127.176(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.023 ENERGY OUT = 128.240(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.24001 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.240 ENERGY OUT = 127.283(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.123 ENERGY OUT = 128.347(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.34700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.347 ENERGY OUT = 127.391(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.223 ENERGY OUT = 128.454(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.45399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.454 ENERGY OUT = 127.499(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.323 ENERGY OUT = 128.561(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.56100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.561 ENERGY OUT = 127.606(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.423 ENERGY OUT = 128.668(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.66800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.668 ENERGY OUT = 127.714(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.523 ENERGY OUT = 128.775(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.77499 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.775 ENERGY OUT = 127.822(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.623 ENERGY OUT = 128.882(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.88200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.882 ENERGY OUT = 127.929(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.723 ENERGY OUT = 128.989(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 128.98900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 128.989 ENERGY OUT = 128.037(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.823 ENERGY OUT = 129.096(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.09599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.096 ENERGY OUT = 128.145(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 139.923 ENERGY OUT = 129.203(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.20300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.203 ENERGY OUT = 128.252(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.023 ENERGY OUT = 129.310(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.31000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.310 ENERGY OUT = 128.360(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.123 ENERGY OUT = 129.416(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.41600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.416 ENERGY OUT = 128.467(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.223 ENERGY OUT = 129.523(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.523 ENERGY OUT = 128.574(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.323 ENERGY OUT = 129.630(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.63000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.630 ENERGY OUT = 128.682(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.423 ENERGY OUT = 129.737(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.73700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.737 ENERGY OUT = 128.790(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.523 ENERGY OUT = 129.844(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.84399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.844 ENERGY OUT = 128.897(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.623 ENERGY OUT = 129.951(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 129.95100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 129.951 ENERGY OUT = 129.005(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.723 ENERGY OUT = 130.057(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.05701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.057 ENERGY OUT = 129.112(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.823 ENERGY OUT = 130.164(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.16400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.164 ENERGY OUT = 129.219(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 140.923 ENERGY OUT = 130.271(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.27100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.271 ENERGY OUT = 129.327(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.023 ENERGY OUT = 130.378(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.37801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.378 ENERGY OUT = 129.435(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.123 ENERGY OUT = 130.484(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.48399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.484 ENERGY OUT = 129.541(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.223 ENERGY OUT = 130.591(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.59100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.591 ENERGY OUT = 129.649(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.323 ENERGY OUT = 130.698(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.69800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.698 ENERGY OUT = 129.757(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.423 ENERGY OUT = 130.805(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.80499 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.805 ENERGY OUT = 129.864(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.523 ENERGY OUT = 130.911(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 130.91100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 130.911 ENERGY OUT = 129.971(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.623 ENERGY OUT = 131.018(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.01801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.018 ENERGY OUT = 130.078(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.723 ENERGY OUT = 131.125(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.12500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.125 ENERGY OUT = 130.186(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.823 ENERGY OUT = 131.232(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.23199 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.232 ENERGY OUT = 130.294(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 141.923 ENERGY OUT = 131.338(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.33800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.338 ENERGY OUT = 130.400(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.023 ENERGY OUT = 131.445(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.44501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.445 ENERGY OUT = 130.508(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.123 ENERGY OUT = 131.552(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.55200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.552 ENERGY OUT = 130.616(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.223 ENERGY OUT = 131.658(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.65800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.658 ENERGY OUT = 130.722(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.323 ENERGY OUT = 131.765(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.76500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.765 ENERGY OUT = 130.830(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.423 ENERGY OUT = 131.872(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.87199 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.872 ENERGY OUT = 130.938(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.523 ENERGY OUT = 131.978(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 131.97800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 131.978 ENERGY OUT = 131.044(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.623 ENERGY OUT = 132.085(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.08501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.085 ENERGY OUT = 131.152(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.723 ENERGY OUT = 132.192(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.19200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.192 ENERGY OUT = 131.260(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.823 ENERGY OUT = 132.298(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.29800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.298 ENERGY OUT = 131.366(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 142.923 ENERGY OUT = 132.405(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.40500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.405 ENERGY OUT = 131.474(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.023 ENERGY OUT = 132.511(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.51100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.511 ENERGY OUT = 131.580(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.123 ENERGY OUT = 132.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.61800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.618 ENERGY OUT = 131.688(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.223 ENERGY OUT = 132.724(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.72400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.724 ENERGY OUT = 131.795(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.323 ENERGY OUT = 132.831(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.83099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.831 ENERGY OUT = 131.902(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.423 ENERGY OUT = 132.938(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 132.93800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 132.938 ENERGY OUT = 132.010(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.523 ENERGY OUT = 133.044(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.04401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.044 ENERGY OUT = 132.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.623 ENERGY OUT = 133.151(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.15100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.151 ENERGY OUT = 132.224(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.723 ENERGY OUT = 133.257(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.25700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.257 ENERGY OUT = 132.331(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.823 ENERGY OUT = 133.364(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.36400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.364 ENERGY OUT = 132.438(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 143.923 ENERGY OUT = 133.470(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.47000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.470 ENERGY OUT = 132.545(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.023 ENERGY OUT = 133.577(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.57700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.577 ENERGY OUT = 132.653(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.123 ENERGY OUT = 133.683(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.68300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.683 ENERGY OUT = 132.759(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.223 ENERGY OUT = 133.790(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.78999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.790 ENERGY OUT = 132.867(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.323 ENERGY OUT = 133.896(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 133.89600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 133.896 ENERGY OUT = 132.973(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.423 ENERGY OUT = 134.003(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.00301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.003 ENERGY OUT = 133.081(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.523 ENERGY OUT = 134.109(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.10899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.109 ENERGY OUT = 133.188(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.623 ENERGY OUT = 134.216(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.21600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.216 ENERGY OUT = 133.295(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.723 ENERGY OUT = 134.322(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.32201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.322 ENERGY OUT = 133.402(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.823 ENERGY OUT = 134.428(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.42799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.428 ENERGY OUT = 133.509(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 144.923 ENERGY OUT = 134.535(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.53500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.535 ENERGY OUT = 133.616(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.023 ENERGY OUT = 134.641(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.64101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.641 ENERGY OUT = 133.723(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.123 ENERGY OUT = 134.748(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.74800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.748 ENERGY OUT = 133.830(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.223 ENERGY OUT = 134.854(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.85400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.854 ENERGY OUT = 133.937(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.323 ENERGY OUT = 134.961(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 134.96100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 134.961 ENERGY OUT = 134.045(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.423 ENERGY OUT = 135.067(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.06700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.067 ENERGY OUT = 134.151(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.523 ENERGY OUT = 135.173(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.17300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.173 ENERGY OUT = 134.258(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.623 ENERGY OUT = 135.280(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.28000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.280 ENERGY OUT = 134.365(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.723 ENERGY OUT = 135.386(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.38600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.386 ENERGY OUT = 134.472(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.823 ENERGY OUT = 135.492(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.49200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.492 ENERGY OUT = 134.579(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 145.923 ENERGY OUT = 135.599(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.59900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.599 ENERGY OUT = 134.686(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.023 ENERGY OUT = 135.705(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.70500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.705 ENERGY OUT = 134.793(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.123 ENERGY OUT = 135.811(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.81100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.811 ENERGY OUT = 134.899(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.223 ENERGY OUT = 135.918(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 135.91800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 135.918 ENERGY OUT = 135.007(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.323 ENERGY OUT = 136.024(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.02400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.024 ENERGY OUT = 135.114(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.423 ENERGY OUT = 136.130(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.13000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.130 ENERGY OUT = 135.220(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.523 ENERGY OUT = 136.236(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.23599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.236 ENERGY OUT = 135.327(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.623 ENERGY OUT = 136.343(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.34300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.343 ENERGY OUT = 135.434(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.723 ENERGY OUT = 136.449(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.44901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.449 ENERGY OUT = 135.541(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.823 ENERGY OUT = 136.555(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.55499 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.555 ENERGY OUT = 135.648(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 146.923 ENERGY OUT = 136.662(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.66200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.662 ENERGY OUT = 135.755(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.023 ENERGY OUT = 136.768(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.76801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.768 ENERGY OUT = 135.862(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.123 ENERGY OUT = 136.874(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.87399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.874 ENERGY OUT = 135.968(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.223 ENERGY OUT = 136.980(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 136.98000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 136.980 ENERGY OUT = 136.075(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.323 ENERGY OUT = 137.086(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.08600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.086 ENERGY OUT = 136.182(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.423 ENERGY OUT = 137.193(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.19299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.193 ENERGY OUT = 136.289(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.523 ENERGY OUT = 137.299(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.29900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.299 ENERGY OUT = 136.396(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.623 ENERGY OUT = 137.405(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.40500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.405 ENERGY OUT = 136.502(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.723 ENERGY OUT = 137.511(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.51100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.511 ENERGY OUT = 136.609(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.823 ENERGY OUT = 137.617(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.61700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.617 ENERGY OUT = 136.715(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 147.923 ENERGY OUT = 137.724(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.72400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.724 ENERGY OUT = 136.823(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.023 ENERGY OUT = 137.830(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.83000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.830 ENERGY OUT = 136.930(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.123 ENERGY OUT = 137.936(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 137.93600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 137.936 ENERGY OUT = 137.036(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.223 ENERGY OUT = 138.042(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.04201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.042 ENERGY OUT = 137.143(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.323 ENERGY OUT = 138.148(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.14799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.148 ENERGY OUT = 137.249(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.423 ENERGY OUT = 138.254(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.25400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.254 ENERGY OUT = 137.356(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.523 ENERGY OUT = 138.360(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.36000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.360 ENERGY OUT = 137.463(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.623 ENERGY OUT = 138.466(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.46600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.466 ENERGY OUT = 137.569(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.723 ENERGY OUT = 138.573(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.57300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.573 ENERGY OUT = 137.677(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.823 ENERGY OUT = 138.679(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.67900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.679 ENERGY OUT = 137.783(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 148.923 ENERGY OUT = 138.785(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.78500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.785 ENERGY OUT = 137.890(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.023 ENERGY OUT = 138.891(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.89101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.891 ENERGY OUT = 137.996(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.123 ENERGY OUT = 138.997(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 138.99699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 138.997 ENERGY OUT = 138.103(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.223 ENERGY OUT = 139.103(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.10300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.103 ENERGY OUT = 138.210(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.323 ENERGY OUT = 139.209(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.20900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.209 ENERGY OUT = 138.316(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.423 ENERGY OUT = 139.315(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.31500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.315 ENERGY OUT = 138.423(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.523 ENERGY OUT = 139.421(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.42101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.421 ENERGY OUT = 138.529(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.623 ENERGY OUT = 139.527(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.52699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.527 ENERGY OUT = 138.636(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.723 ENERGY OUT = 139.633(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.63300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.633 ENERGY OUT = 138.742(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.823 ENERGY OUT = 139.739(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.73900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.739 ENERGY OUT = 138.849(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 149.923 ENERGY OUT = 139.845(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.84500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.845 ENERGY OUT = 138.956(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.023 ENERGY OUT = 139.951(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 139.95100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 139.951 ENERGY OUT = 139.062(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.123 ENERGY OUT = 140.057(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.05701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.057 ENERGY OUT = 139.169(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.223 ENERGY OUT = 140.163(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.16299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.163 ENERGY OUT = 139.275(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.323 ENERGY OUT = 140.269(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.26900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.269 ENERGY OUT = 139.382(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.423 ENERGY OUT = 140.375(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.37500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.375 ENERGY OUT = 139.488(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.523 ENERGY OUT = 140.481(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.48100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.481 ENERGY OUT = 139.595(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.623 ENERGY OUT = 140.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.58701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.587 ENERGY OUT = 139.702(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.723 ENERGY OUT = 140.693(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.69299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.693 ENERGY OUT = 139.808(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.823 ENERGY OUT = 140.799(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.79900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.799 ENERGY OUT = 139.915(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 150.923 ENERGY OUT = 140.905(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 140.90500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 140.905 ENERGY OUT = 140.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.023 ENERGY OUT = 141.011(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.01100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.011 ENERGY OUT = 140.128(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.123 ENERGY OUT = 141.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.11700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.117 ENERGY OUT = 140.234(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.223 ENERGY OUT = 141.222(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.22200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.222 ENERGY OUT = 140.340(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.323 ENERGY OUT = 141.328(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.32800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.328 ENERGY OUT = 140.446(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.423 ENERGY OUT = 141.434(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.43401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.434 ENERGY OUT = 140.553(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.523 ENERGY OUT = 141.540(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.53999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.540 ENERGY OUT = 140.660(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.623 ENERGY OUT = 141.646(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.64600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.646 ENERGY OUT = 140.766(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.723 ENERGY OUT = 141.752(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.75200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.752 ENERGY OUT = 140.873(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.823 ENERGY OUT = 141.858(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.85800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.858 ENERGY OUT = 140.979(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 151.923 ENERGY OUT = 141.964(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 141.96400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 141.964 ENERGY OUT = 141.086(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.023 ENERGY OUT = 142.069(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.06900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.069 ENERGY OUT = 141.191(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.123 ENERGY OUT = 142.175(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.17500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.175 ENERGY OUT = 141.298(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.223 ENERGY OUT = 142.281(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.28101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.281 ENERGY OUT = 141.404(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.323 ENERGY OUT = 142.387(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.38699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.387 ENERGY OUT = 141.511(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.423 ENERGY OUT = 142.493(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.49300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.493 ENERGY OUT = 141.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.523 ENERGY OUT = 142.598(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.59801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.598 ENERGY OUT = 141.723(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.623 ENERGY OUT = 142.704(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.70399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.704 ENERGY OUT = 141.830(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.723 ENERGY OUT = 142.810(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.81000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.810 ENERGY OUT = 141.936(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.823 ENERGY OUT = 142.916(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 142.91600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 142.916 ENERGY OUT = 142.043(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 152.923 ENERGY OUT = 143.022(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.02200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.022 ENERGY OUT = 142.149(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.023 ENERGY OUT = 143.127(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.12700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.127 ENERGY OUT = 142.255(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.123 ENERGY OUT = 143.233(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.23300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.233 ENERGY OUT = 142.361(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.223 ENERGY OUT = 143.339(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.33900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.339 ENERGY OUT = 142.468(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.323 ENERGY OUT = 143.445(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.44501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.445 ENERGY OUT = 142.574(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.423 ENERGY OUT = 143.550(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.55000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.550 ENERGY OUT = 142.680(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.523 ENERGY OUT = 143.656(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.65601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.656 ENERGY OUT = 142.786(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.623 ENERGY OUT = 143.762(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.76199 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.762 ENERGY OUT = 142.893(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.723 ENERGY OUT = 143.867(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.86700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.867 ENERGY OUT = 142.999(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.823 ENERGY OUT = 143.973(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 143.97301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 143.973 ENERGY OUT = 143.105(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 153.923 ENERGY OUT = 144.079(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.07899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.079 ENERGY OUT = 143.212(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.023 ENERGY OUT = 144.184(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.18401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.184 ENERGY OUT = 143.317(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.123 ENERGY OUT = 144.290(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.28999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.290 ENERGY OUT = 143.424(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.223 ENERGY OUT = 144.396(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.39600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.396 ENERGY OUT = 143.530(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.323 ENERGY OUT = 144.501(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.50101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.501 ENERGY OUT = 143.636(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.423 ENERGY OUT = 144.607(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.60699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.607 ENERGY OUT = 143.742(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.523 ENERGY OUT = 144.713(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.71300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.713 ENERGY OUT = 143.849(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.623 ENERGY OUT = 144.819(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.81900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.819 ENERGY OUT = 143.955(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.723 ENERGY OUT = 144.924(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 144.92400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 144.924 ENERGY OUT = 144.061(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.823 ENERGY OUT = 145.030(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.03000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.030 ENERGY OUT = 144.167(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 154.923 ENERGY OUT = 145.135(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.13499 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.135 ENERGY OUT = 144.273(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 155.023 ENERGY OUT = 145.241(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.24100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.241 ENERGY OUT = 144.379(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 155.123 ENERGY OUT = 145.347(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.34700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.347 ENERGY OUT = 144.486(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 155.223 ENERGY OUT = 145.452(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.45200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.452 ENERGY OUT = 144.592(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 155.323 ENERGY OUT = 145.558(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.55800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.558 ENERGY OUT = 144.698(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 155.423 ENERGY OUT = 145.663(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.66299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.663 ENERGY OUT = 144.804(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 512 STEPS ENERGY IN = 155.523 ENERGY OUT = 145.769(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.76900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.769 ENERGY OUT = 144.910(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 155.623 ENERGY OUT = 145.875(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.87500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.875 ENERGY OUT = 145.017(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 155.723 ENERGY OUT = 145.981(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 145.98100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 145.981 ENERGY OUT = 145.123(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 155.823 ENERGY OUT = 146.086(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.08600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.086 ENERGY OUT = 145.229(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 155.923 ENERGY OUT = 146.192(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.19200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.192 ENERGY OUT = 145.335(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.023 ENERGY OUT = 146.297(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.29700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.297 ENERGY OUT = 145.441(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.123 ENERGY OUT = 146.403(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.40300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.403 ENERGY OUT = 145.547(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.223 ENERGY OUT = 146.508(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.50800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.508 ENERGY OUT = 145.653(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.323 ENERGY OUT = 146.614(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.61400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.614 ENERGY OUT = 145.759(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.423 ENERGY OUT = 146.720(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.72000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.720 ENERGY OUT = 145.866(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.523 ENERGY OUT = 146.825(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.82500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.825 ENERGY OUT = 145.971(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.623 ENERGY OUT = 146.930(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 146.92999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 146.930 ENERGY OUT = 146.077(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.723 ENERGY OUT = 147.036(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.03600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.036 ENERGY OUT = 146.183(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.823 ENERGY OUT = 147.142(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.14200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.142 ENERGY OUT = 146.290(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 156.923 ENERGY OUT = 147.247(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.24699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.247 ENERGY OUT = 146.395(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.023 ENERGY OUT = 147.352(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.35201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.352 ENERGY OUT = 146.501(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.123 ENERGY OUT = 147.458(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.45799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.458 ENERGY OUT = 146.607(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.223 ENERGY OUT = 147.563(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.56300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.563 ENERGY OUT = 146.713(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.323 ENERGY OUT = 147.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.66901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.669 ENERGY OUT = 146.819(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.423 ENERGY OUT = 147.774(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.77400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.774 ENERGY OUT = 146.925(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.523 ENERGY OUT = 147.880(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.88000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.880 ENERGY OUT = 147.031(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.623 ENERGY OUT = 147.985(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 147.98500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 147.985 ENERGY OUT = 147.137(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.723 ENERGY OUT = 148.091(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.09100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.091 ENERGY OUT = 147.243(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.823 ENERGY OUT = 148.196(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.19600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.196 ENERGY OUT = 147.349(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 157.923 ENERGY OUT = 148.301(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.30099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.301 ENERGY OUT = 147.454(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.023 ENERGY OUT = 148.407(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.40700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.407 ENERGY OUT = 147.561(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.123 ENERGY OUT = 148.512(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.51199 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.512 ENERGY OUT = 147.666(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.223 ENERGY OUT = 148.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.61800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.618 ENERGY OUT = 147.773(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.323 ENERGY OUT = 148.723(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.723 ENERGY OUT = 147.878(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.423 ENERGY OUT = 148.828(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.82800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.828 ENERGY OUT = 147.984(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.523 ENERGY OUT = 148.934(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 148.93401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 148.934 ENERGY OUT = 148.090(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.623 ENERGY OUT = 149.039(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.03900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.039 ENERGY OUT = 148.196(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.723 ENERGY OUT = 149.144(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.14400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.144 ENERGY OUT = 148.301(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.823 ENERGY OUT = 149.250(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.25000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.250 ENERGY OUT = 148.408(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 158.923 ENERGY OUT = 149.355(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.35500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.355 ENERGY OUT = 148.513(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.023 ENERGY OUT = 149.461(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.46100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.461 ENERGY OUT = 148.620(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.123 ENERGY OUT = 149.566(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.56599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.566 ENERGY OUT = 148.725(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.223 ENERGY OUT = 149.671(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.67101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.671 ENERGY OUT = 148.831(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.323 ENERGY OUT = 149.777(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.77699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.777 ENERGY OUT = 148.938(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.423 ENERGY OUT = 149.882(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.88200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.882 ENERGY OUT = 149.043(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.523 ENERGY OUT = 149.987(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 149.98700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 149.987 ENERGY OUT = 149.148(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.623 ENERGY OUT = 150.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.09200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.092 ENERGY OUT = 149.254(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.723 ENERGY OUT = 150.198(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.19800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.198 ENERGY OUT = 149.360(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.823 ENERGY OUT = 150.303(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.30299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.303 ENERGY OUT = 149.466(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 159.923 ENERGY OUT = 150.408(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.40800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.408 ENERGY OUT = 149.571(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.023 ENERGY OUT = 150.514(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.51401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.514 ENERGY OUT = 149.678(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.123 ENERGY OUT = 150.619(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.61900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.619 ENERGY OUT = 149.783(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.223 ENERGY OUT = 150.724(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.72400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.724 ENERGY OUT = 149.889(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.323 ENERGY OUT = 150.829(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.82899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.829 ENERGY OUT = 149.994(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.423 ENERGY OUT = 150.935(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 150.93500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 150.935 ENERGY OUT = 150.101(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.523 ENERGY OUT = 151.040(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.03999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.040 ENERGY OUT = 150.206(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.623 ENERGY OUT = 151.145(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.14500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.145 ENERGY OUT = 150.312(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.723 ENERGY OUT = 151.250(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.25000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.250 ENERGY OUT = 150.417(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.823 ENERGY OUT = 151.355(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.35500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.355 ENERGY OUT = 150.523(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 160.923 ENERGY OUT = 151.461(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.46100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.461 ENERGY OUT = 150.629(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.023 ENERGY OUT = 151.566(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.56599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.566 ENERGY OUT = 150.735(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.123 ENERGY OUT = 151.671(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.67101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.671 ENERGY OUT = 150.840(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.223 ENERGY OUT = 151.776(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.77600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.776 ENERGY OUT = 150.946(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.323 ENERGY OUT = 151.882(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.88200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.882 ENERGY OUT = 151.052(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.423 ENERGY OUT = 151.987(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 151.98700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 151.987 ENERGY OUT = 151.158(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.523 ENERGY OUT = 152.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.09200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.092 ENERGY OUT = 151.263(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.623 ENERGY OUT = 152.197(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.19701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.197 ENERGY OUT = 151.369(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.723 ENERGY OUT = 152.302(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.30200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.302 ENERGY OUT = 151.474(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.823 ENERGY OUT = 152.407(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.40700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.407 ENERGY OUT = 151.580(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 161.923 ENERGY OUT = 152.513(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.51300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.513 ENERGY OUT = 151.686(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.023 ENERGY OUT = 152.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.61800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.618 ENERGY OUT = 151.792(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.123 ENERGY OUT = 152.723(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.723 ENERGY OUT = 151.897(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.223 ENERGY OUT = 152.828(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.82800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.828 ENERGY OUT = 152.003(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.323 ENERGY OUT = 152.933(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 152.93300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 152.933 ENERGY OUT = 152.108(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.423 ENERGY OUT = 153.038(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.03799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.038 ENERGY OUT = 152.214(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.523 ENERGY OUT = 153.144(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.14400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.144 ENERGY OUT = 152.320(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.623 ENERGY OUT = 153.249(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.24899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.249 ENERGY OUT = 152.426(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.723 ENERGY OUT = 153.354(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.35400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.354 ENERGY OUT = 152.531(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.823 ENERGY OUT = 153.459(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.45900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.459 ENERGY OUT = 152.636(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 162.923 ENERGY OUT = 153.564(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.56400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.564 ENERGY OUT = 152.742(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.023 ENERGY OUT = 153.669(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.66901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.669 ENERGY OUT = 152.847(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.123 ENERGY OUT = 153.774(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.77400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.774 ENERGY OUT = 152.953(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.223 ENERGY OUT = 153.879(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.87900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.879 ENERGY OUT = 153.058(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.323 ENERGY OUT = 153.984(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 153.98399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 153.984 ENERGY OUT = 153.164(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.423 ENERGY OUT = 154.089(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.08900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.089 ENERGY OUT = 153.269(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.523 ENERGY OUT = 154.194(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.19400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.194 ENERGY OUT = 153.375(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.623 ENERGY OUT = 154.299(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.29900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.299 ENERGY OUT = 153.480(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.723 ENERGY OUT = 154.404(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.40401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.404 ENERGY OUT = 153.586(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.823 ENERGY OUT = 154.509(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.50900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.509 ENERGY OUT = 153.691(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 163.923 ENERGY OUT = 154.615(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.61501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.615 ENERGY OUT = 153.798(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.023 ENERGY OUT = 154.719(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.71899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.719 ENERGY OUT = 153.902(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.123 ENERGY OUT = 154.824(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.82401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.824 ENERGY OUT = 154.008(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.223 ENERGY OUT = 154.929(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 154.92900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 154.929 ENERGY OUT = 154.113(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.323 ENERGY OUT = 155.035(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.03500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.035 ENERGY OUT = 154.220(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.423 ENERGY OUT = 155.140(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.14000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.140 ENERGY OUT = 154.325(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.523 ENERGY OUT = 155.245(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.24500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.245 ENERGY OUT = 154.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.623 ENERGY OUT = 155.350(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.35001 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.350 ENERGY OUT = 154.536(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.723 ENERGY OUT = 155.455(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.45500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.455 ENERGY OUT = 154.641(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.823 ENERGY OUT = 155.560(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.56000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.560 ENERGY OUT = 154.747(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 164.923 ENERGY OUT = 155.664(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.66400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.664 ENERGY OUT = 154.851(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.023 ENERGY OUT = 155.769(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.76900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.769 ENERGY OUT = 154.957(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.123 ENERGY OUT = 155.874(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.87399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.874 ENERGY OUT = 155.062(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.223 ENERGY OUT = 155.979(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 155.97900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 155.979 ENERGY OUT = 155.168(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.323 ENERGY OUT = 156.084(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.08400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.084 ENERGY OUT = 155.273(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.423 ENERGY OUT = 156.189(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.18900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.189 ENERGY OUT = 155.379(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.523 ENERGY OUT = 156.294(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.29401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.294 ENERGY OUT = 155.484(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.623 ENERGY OUT = 156.399(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.39900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.399 ENERGY OUT = 155.590(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.723 ENERGY OUT = 156.504(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.50400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.504 ENERGY OUT = 155.695(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.823 ENERGY OUT = 156.609(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.60899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.609 ENERGY OUT = 155.800(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 165.923 ENERGY OUT = 156.714(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.71400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.714 ENERGY OUT = 155.906(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.023 ENERGY OUT = 156.819(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.81900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.819 ENERGY OUT = 156.011(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.123 ENERGY OUT = 156.924(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 156.92400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 156.924 ENERGY OUT = 156.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.223 ENERGY OUT = 157.029(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.02901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.029 ENERGY OUT = 156.222(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.323 ENERGY OUT = 157.133(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.13300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.133 ENERGY OUT = 156.327(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.423 ENERGY OUT = 157.238(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.23801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.238 ENERGY OUT = 156.432(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.523 ENERGY OUT = 157.343(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.34300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.343 ENERGY OUT = 156.538(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.623 ENERGY OUT = 157.448(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.44800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.448 ENERGY OUT = 156.643(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.723 ENERGY OUT = 157.553(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.55299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.553 ENERGY OUT = 156.749(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.823 ENERGY OUT = 157.658(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.65800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.658 ENERGY OUT = 156.854(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 166.923 ENERGY OUT = 157.763(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.76300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.763 ENERGY OUT = 156.959(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.023 ENERGY OUT = 157.868(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.86800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.868 ENERGY OUT = 157.065(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.123 ENERGY OUT = 157.972(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 157.97200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 157.972 ENERGY OUT = 157.169(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.223 ENERGY OUT = 158.077(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.07700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.077 ENERGY OUT = 157.275(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.323 ENERGY OUT = 158.182(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.18201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.182 ENERGY OUT = 157.380(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.423 ENERGY OUT = 158.287(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.28700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.287 ENERGY OUT = 157.486(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.523 ENERGY OUT = 158.392(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.39200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.392 ENERGY OUT = 157.591(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.623 ENERGY OUT = 158.497(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.49699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.497 ENERGY OUT = 157.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.723 ENERGY OUT = 158.601(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.60100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.601 ENERGY OUT = 157.801(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.823 ENERGY OUT = 158.706(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.70599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.706 ENERGY OUT = 157.906(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 167.923 ENERGY OUT = 158.811(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.81100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.811 ENERGY OUT = 158.012(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.023 ENERGY OUT = 158.916(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 158.91600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 158.916 ENERGY OUT = 158.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.123 ENERGY OUT = 159.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.02100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.021 ENERGY OUT = 158.223(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.223 ENERGY OUT = 159.125(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.12500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.125 ENERGY OUT = 158.327(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.323 ENERGY OUT = 159.230(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.23000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.230 ENERGY OUT = 158.433(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.423 ENERGY OUT = 159.335(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.33501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.335 ENERGY OUT = 158.538(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.523 ENERGY OUT = 159.440(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.44000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.440 ENERGY OUT = 158.644(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.623 ENERGY OUT = 159.544(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.54401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.544 ENERGY OUT = 158.748(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.723 ENERGY OUT = 159.649(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.64900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.649 ENERGY OUT = 158.853(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.823 ENERGY OUT = 159.754(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.75400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.754 ENERGY OUT = 158.959(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 168.923 ENERGY OUT = 159.859(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.85899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.859 ENERGY OUT = 159.064(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.023 ENERGY OUT = 159.963(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 159.96300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 159.963 ENERGY OUT = 159.169(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.123 ENERGY OUT = 160.068(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.06799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.068 ENERGY OUT = 159.274(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.223 ENERGY OUT = 160.173(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.17300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.173 ENERGY OUT = 159.380(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.323 ENERGY OUT = 160.278(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.27800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.278 ENERGY OUT = 159.485(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.423 ENERGY OUT = 160.382(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.38200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.382 ENERGY OUT = 159.590(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.523 ENERGY OUT = 160.487(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.48700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.487 ENERGY OUT = 159.695(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.623 ENERGY OUT = 160.592(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.59200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.592 ENERGY OUT = 159.800(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.723 ENERGY OUT = 160.696(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.69600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.696 ENERGY OUT = 159.905(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.823 ENERGY OUT = 160.801(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.80099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.801 ENERGY OUT = 160.010(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 169.923 ENERGY OUT = 160.906(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 160.90601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 160.906 ENERGY OUT = 160.116(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.023 ENERGY OUT = 161.011(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.01100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.011 ENERGY OUT = 160.221(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.123 ENERGY OUT = 161.115(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.11501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.115 ENERGY OUT = 160.326(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.223 ENERGY OUT = 161.220(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.22000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.220 ENERGY OUT = 160.431(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.323 ENERGY OUT = 161.325(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.32500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.325 ENERGY OUT = 160.536(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.423 ENERGY OUT = 161.429(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.42900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.429 ENERGY OUT = 160.641(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.523 ENERGY OUT = 161.534(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.53400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.534 ENERGY OUT = 160.746(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.623 ENERGY OUT = 161.639(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.63901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.639 ENERGY OUT = 160.852(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.723 ENERGY OUT = 161.743(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.74300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.743 ENERGY OUT = 160.956(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.823 ENERGY OUT = 161.848(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.84801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.848 ENERGY OUT = 161.062(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 170.923 ENERGY OUT = 161.952(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 161.95200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 161.952 ENERGY OUT = 161.166(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.023 ENERGY OUT = 162.057(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.05701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.057 ENERGY OUT = 161.271(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.123 ENERGY OUT = 162.162(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.16200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.162 ENERGY OUT = 161.377(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.223 ENERGY OUT = 162.266(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.26601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.266 ENERGY OUT = 161.481(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.323 ENERGY OUT = 162.371(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.37100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.371 ENERGY OUT = 161.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.423 ENERGY OUT = 162.476(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.47600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.476 ENERGY OUT = 161.692(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.523 ENERGY OUT = 162.580(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.58000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.580 ENERGY OUT = 161.797(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.623 ENERGY OUT = 162.685(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.68500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.685 ENERGY OUT = 161.902(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.723 ENERGY OUT = 162.789(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.78900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.789 ENERGY OUT = 162.006(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.823 ENERGY OUT = 162.894(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.89400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.894 ENERGY OUT = 162.112(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 171.923 ENERGY OUT = 162.999(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 162.99899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 162.999 ENERGY OUT = 162.217(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.023 ENERGY OUT = 163.103(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.10300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.103 ENERGY OUT = 162.322(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.123 ENERGY OUT = 163.208(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.20799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.208 ENERGY OUT = 162.427(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.223 ENERGY OUT = 163.312(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.31200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.312 ENERGY OUT = 162.532(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.323 ENERGY OUT = 163.417(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.41701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.417 ENERGY OUT = 162.637(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.423 ENERGY OUT = 163.521(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.52100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.521 ENERGY OUT = 162.741(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.523 ENERGY OUT = 163.626(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.62601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.626 ENERGY OUT = 162.847(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.623 ENERGY OUT = 163.731(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.73100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.731 ENERGY OUT = 162.952(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.723 ENERGY OUT = 163.835(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.83501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.835 ENERGY OUT = 163.057(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.823 ENERGY OUT = 163.940(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 163.94000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 163.940 ENERGY OUT = 163.162(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 172.923 ENERGY OUT = 164.044(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.04401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.044 ENERGY OUT = 163.267(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.023 ENERGY OUT = 164.149(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.14900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.149 ENERGY OUT = 163.372(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.123 ENERGY OUT = 164.253(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.25301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.253 ENERGY OUT = 163.476(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.223 ENERGY OUT = 164.358(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.35800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.358 ENERGY OUT = 163.582(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.323 ENERGY OUT = 164.462(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.46201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.462 ENERGY OUT = 163.686(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.423 ENERGY OUT = 164.567(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.56700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.567 ENERGY OUT = 163.792(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.523 ENERGY OUT = 164.671(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.67101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.671 ENERGY OUT = 163.896(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.623 ENERGY OUT = 164.776(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.77600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.776 ENERGY OUT = 164.001(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.723 ENERGY OUT = 164.880(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.88000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.880 ENERGY OUT = 164.106(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.823 ENERGY OUT = 164.985(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 164.98500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 164.985 ENERGY OUT = 164.211(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 173.923 ENERGY OUT = 165.089(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.08900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.089 ENERGY OUT = 164.316(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.023 ENERGY OUT = 165.194(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.19400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.194 ENERGY OUT = 164.421(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.123 ENERGY OUT = 165.298(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.29800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.298 ENERGY OUT = 164.525(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.223 ENERGY OUT = 165.403(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.40300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.403 ENERGY OUT = 164.631(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.323 ENERGY OUT = 165.507(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.50700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.507 ENERGY OUT = 164.735(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.423 ENERGY OUT = 165.612(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.61200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.612 ENERGY OUT = 164.841(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.523 ENERGY OUT = 165.716(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.71600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.716 ENERGY OUT = 164.945(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.623 ENERGY OUT = 165.820(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.82001 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.820 ENERGY OUT = 165.050(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.723 ENERGY OUT = 165.925(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 165.92500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 165.925 ENERGY OUT = 165.155(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.823 ENERGY OUT = 166.029(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.02901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.029 ENERGY OUT = 165.259(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 174.923 ENERGY OUT = 166.134(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.13400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.134 ENERGY OUT = 165.365(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.023 ENERGY OUT = 166.238(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.23801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.238 ENERGY OUT = 165.469(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.123 ENERGY OUT = 166.343(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.34300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.343 ENERGY OUT = 165.575(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.223 ENERGY OUT = 166.447(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.44701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.447 ENERGY OUT = 165.679(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.323 ENERGY OUT = 166.551(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.55099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.551 ENERGY OUT = 165.783(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.423 ENERGY OUT = 166.656(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.65601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.656 ENERGY OUT = 165.889(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.523 ENERGY OUT = 166.760(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.75999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.760 ENERGY OUT = 165.993(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.623 ENERGY OUT = 166.865(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.86501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.865 ENERGY OUT = 166.099(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.723 ENERGY OUT = 166.969(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 166.96899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 166.969 ENERGY OUT = 166.203(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.823 ENERGY OUT = 167.073(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.07300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.073 ENERGY OUT = 166.307(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 175.923 ENERGY OUT = 167.178(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.17799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.178 ENERGY OUT = 166.413(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.023 ENERGY OUT = 167.282(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.28200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.282 ENERGY OUT = 166.517(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.123 ENERGY OUT = 167.387(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.38699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.387 ENERGY OUT = 166.623(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.223 ENERGY OUT = 167.491(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.49100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.491 ENERGY OUT = 166.727(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.323 ENERGY OUT = 167.595(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.59500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.595 ENERGY OUT = 166.831(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.423 ENERGY OUT = 167.700(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.70000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.700 ENERGY OUT = 166.937(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.523 ENERGY OUT = 167.804(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.80400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.804 ENERGY OUT = 167.041(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.623 ENERGY OUT = 167.908(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 167.90800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 167.908 ENERGY OUT = 167.146(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.723 ENERGY OUT = 168.013(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.01300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.013 ENERGY OUT = 167.251(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.823 ENERGY OUT = 168.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.11700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.117 ENERGY OUT = 167.355(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 176.923 ENERGY OUT = 168.221(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.22099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.221 ENERGY OUT = 167.460(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.023 ENERGY OUT = 168.326(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.32600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.326 ENERGY OUT = 167.565(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.123 ENERGY OUT = 168.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.42999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.430 ENERGY OUT = 167.670(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.223 ENERGY OUT = 168.534(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.53400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.534 ENERGY OUT = 167.774(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.323 ENERGY OUT = 168.639(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.63901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.639 ENERGY OUT = 167.879(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.423 ENERGY OUT = 168.743(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.74300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.743 ENERGY OUT = 167.984(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.523 ENERGY OUT = 168.847(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.84700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.847 ENERGY OUT = 168.088(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.623 ENERGY OUT = 168.952(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 168.95200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 168.952 ENERGY OUT = 168.194(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.723 ENERGY OUT = 169.056(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.05600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.056 ENERGY OUT = 168.298(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.823 ENERGY OUT = 169.160(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.16000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.160 ENERGY OUT = 168.402(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 177.923 ENERGY OUT = 169.265(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.26500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.265 ENERGY OUT = 168.508(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.023 ENERGY OUT = 169.369(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.36900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.369 ENERGY OUT = 168.612(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.123 ENERGY OUT = 169.473(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.47301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.473 ENERGY OUT = 168.717(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.223 ENERGY OUT = 169.577(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.57700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.577 ENERGY OUT = 168.821(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.323 ENERGY OUT = 169.682(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.68201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.682 ENERGY OUT = 168.926(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.423 ENERGY OUT = 169.786(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.78600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.786 ENERGY OUT = 169.031(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.523 ENERGY OUT = 169.890(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.89000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.890 ENERGY OUT = 169.135(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.623 ENERGY OUT = 169.994(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 169.99400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 169.994 ENERGY OUT = 169.240(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.723 ENERGY OUT = 170.099(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.09900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.099 ENERGY OUT = 169.345(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.823 ENERGY OUT = 170.203(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.20300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.203 ENERGY OUT = 169.449(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 178.923 ENERGY OUT = 170.307(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.30701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.307 ENERGY OUT = 169.554(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.023 ENERGY OUT = 170.411(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.41100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.411 ENERGY OUT = 169.658(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.123 ENERGY OUT = 170.516(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.51601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.516 ENERGY OUT = 169.763(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.223 ENERGY OUT = 170.620(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.62000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.620 ENERGY OUT = 169.868(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.323 ENERGY OUT = 170.724(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.72400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.724 ENERGY OUT = 169.972(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.423 ENERGY OUT = 170.828(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.82800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.828 ENERGY OUT = 170.077(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.523 ENERGY OUT = 170.933(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 170.93300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 170.933 ENERGY OUT = 170.182(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.623 ENERGY OUT = 171.037(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.03700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.037 ENERGY OUT = 170.286(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.723 ENERGY OUT = 171.141(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.14101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.141 ENERGY OUT = 170.391(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.823 ENERGY OUT = 171.245(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.24500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.245 ENERGY OUT = 170.495(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 179.923 ENERGY OUT = 171.349(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.34900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.349 ENERGY OUT = 170.600(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.023 ENERGY OUT = 171.454(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.45399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.454 ENERGY OUT = 170.705(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.123 ENERGY OUT = 171.558(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.55800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.558 ENERGY OUT = 170.809(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.223 ENERGY OUT = 171.662(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.66200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.662 ENERGY OUT = 170.914(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.323 ENERGY OUT = 171.766(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.76601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.766 ENERGY OUT = 171.018(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.423 ENERGY OUT = 171.870(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.87000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.870 ENERGY OUT = 171.122(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.523 ENERGY OUT = 171.975(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 171.97501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 171.975 ENERGY OUT = 171.228(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.623 ENERGY OUT = 172.079(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.07899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.079 ENERGY OUT = 171.332(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.723 ENERGY OUT = 172.183(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.18300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.183 ENERGY OUT = 171.437(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.823 ENERGY OUT = 172.287(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.28700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.287 ENERGY OUT = 171.541(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 180.923 ENERGY OUT = 172.391(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.39101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.391 ENERGY OUT = 171.645(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.023 ENERGY OUT = 172.495(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.49500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.495 ENERGY OUT = 171.750(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.123 ENERGY OUT = 172.599(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.59900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.599 ENERGY OUT = 171.854(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.223 ENERGY OUT = 172.704(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.70399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.704 ENERGY OUT = 171.960(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.323 ENERGY OUT = 172.808(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.80800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.808 ENERGY OUT = 172.064(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.423 ENERGY OUT = 172.912(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 172.91200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 172.912 ENERGY OUT = 172.168(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.523 ENERGY OUT = 173.016(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.01601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.016 ENERGY OUT = 172.273(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.623 ENERGY OUT = 173.120(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.12000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.120 ENERGY OUT = 172.377(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.723 ENERGY OUT = 173.224(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.22400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.224 ENERGY OUT = 172.481(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.823 ENERGY OUT = 173.328(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.32800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.328 ENERGY OUT = 172.586(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 181.923 ENERGY OUT = 173.432(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.43201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.432 ENERGY OUT = 172.690(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.023 ENERGY OUT = 173.537(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.53700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.537 ENERGY OUT = 172.796(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.123 ENERGY OUT = 173.641(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.64101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.641 ENERGY OUT = 172.900(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.223 ENERGY OUT = 173.745(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.74500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.745 ENERGY OUT = 173.004(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.323 ENERGY OUT = 173.849(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.84900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.849 ENERGY OUT = 173.109(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.423 ENERGY OUT = 173.953(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 173.95300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 173.953 ENERGY OUT = 173.213(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.523 ENERGY OUT = 174.057(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.05701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.057 ENERGY OUT = 173.317(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.623 ENERGY OUT = 174.161(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.16100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.161 ENERGY OUT = 173.422(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.723 ENERGY OUT = 174.265(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.26500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.265 ENERGY OUT = 173.526(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.823 ENERGY OUT = 174.369(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.36900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.369 ENERGY OUT = 173.631(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 182.923 ENERGY OUT = 174.473(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.47301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.473 ENERGY OUT = 173.735(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.023 ENERGY OUT = 174.577(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.57700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.577 ENERGY OUT = 173.839(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.123 ENERGY OUT = 174.681(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.68100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.681 ENERGY OUT = 173.944(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.223 ENERGY OUT = 174.786(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.78600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.786 ENERGY OUT = 174.049(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.323 ENERGY OUT = 174.890(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.89000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.890 ENERGY OUT = 174.153(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.423 ENERGY OUT = 174.994(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 174.99400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 174.994 ENERGY OUT = 174.258(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.523 ENERGY OUT = 175.098(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.09801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.098 ENERGY OUT = 174.362(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.623 ENERGY OUT = 175.202(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.20200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.202 ENERGY OUT = 174.466(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.723 ENERGY OUT = 175.306(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.30600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.306 ENERGY OUT = 174.571(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.823 ENERGY OUT = 175.410(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.41000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.410 ENERGY OUT = 174.675(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 183.923 ENERGY OUT = 175.514(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.51401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.514 ENERGY OUT = 174.780(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.023 ENERGY OUT = 175.618(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.61800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.618 ENERGY OUT = 174.884(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.123 ENERGY OUT = 175.722(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.72200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.722 ENERGY OUT = 174.988(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.223 ENERGY OUT = 175.826(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.82600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.826 ENERGY OUT = 175.093(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.323 ENERGY OUT = 175.930(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 175.92999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 175.930 ENERGY OUT = 175.197(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.423 ENERGY OUT = 176.034(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.03400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.034 ENERGY OUT = 175.301(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.523 ENERGY OUT = 176.138(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.13800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.138 ENERGY OUT = 175.406(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.623 ENERGY OUT = 176.242(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.24200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.242 ENERGY OUT = 175.510(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.723 ENERGY OUT = 176.346(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.34599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.346 ENERGY OUT = 175.615(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.823 ENERGY OUT = 176.450(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.45000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.450 ENERGY OUT = 175.719(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 184.923 ENERGY OUT = 176.554(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.55400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.554 ENERGY OUT = 175.823(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.023 ENERGY OUT = 176.658(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.65800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.658 ENERGY OUT = 175.928(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.123 ENERGY OUT = 176.762(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.76199 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.762 ENERGY OUT = 176.032(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.223 ENERGY OUT = 176.866(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.86600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.866 ENERGY OUT = 176.136(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.323 ENERGY OUT = 176.970(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 176.97000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 176.970 ENERGY OUT = 176.241(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.423 ENERGY OUT = 177.074(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.07401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.074 ENERGY OUT = 176.345(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.523 ENERGY OUT = 177.177(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.17700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.177 ENERGY OUT = 176.448(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.623 ENERGY OUT = 177.281(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.28101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.281 ENERGY OUT = 176.553(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.723 ENERGY OUT = 177.385(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.38499 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.385 ENERGY OUT = 176.657(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.823 ENERGY OUT = 177.489(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.48900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.489 ENERGY OUT = 176.762(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 185.923 ENERGY OUT = 177.593(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.59300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.593 ENERGY OUT = 176.866(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.023 ENERGY OUT = 177.697(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.69701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.697 ENERGY OUT = 176.970(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.123 ENERGY OUT = 177.801(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.80099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.801 ENERGY OUT = 177.075(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.223 ENERGY OUT = 177.905(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 177.90500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 177.905 ENERGY OUT = 177.179(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.323 ENERGY OUT = 178.009(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.00900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.009 ENERGY OUT = 177.283(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.423 ENERGY OUT = 178.113(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.11301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.113 ENERGY OUT = 177.388(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.523 ENERGY OUT = 178.217(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.21700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.217 ENERGY OUT = 177.492(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.623 ENERGY OUT = 178.321(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.32100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.321 ENERGY OUT = 177.596(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.723 ENERGY OUT = 178.425(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.42500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.425 ENERGY OUT = 177.701(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.823 ENERGY OUT = 178.529(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.52901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.529 ENERGY OUT = 177.805(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 186.923 ENERGY OUT = 178.632(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.63200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.632 ENERGY OUT = 177.908(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.023 ENERGY OUT = 178.736(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.73599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.736 ENERGY OUT = 178.013(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.123 ENERGY OUT = 178.840(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.84000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.840 ENERGY OUT = 178.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.223 ENERGY OUT = 178.944(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 178.94400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 178.944 ENERGY OUT = 178.222(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.323 ENERGY OUT = 179.048(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.04800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.048 ENERGY OUT = 178.326(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.423 ENERGY OUT = 179.152(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.15199 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.152 ENERGY OUT = 178.430(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.523 ENERGY OUT = 179.256(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.25600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.256 ENERGY OUT = 178.535(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.623 ENERGY OUT = 179.360(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.36000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.360 ENERGY OUT = 178.639(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.723 ENERGY OUT = 179.464(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.46400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.464 ENERGY OUT = 178.743(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.823 ENERGY OUT = 179.567(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.56700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.567 ENERGY OUT = 178.847(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 187.923 ENERGY OUT = 179.671(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.67101 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.671 ENERGY OUT = 178.951(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.023 ENERGY OUT = 179.775(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.77499 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.775 ENERGY OUT = 179.055(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.123 ENERGY OUT = 179.879(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.87900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.879 ENERGY OUT = 179.160(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.223 ENERGY OUT = 179.983(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 179.98300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 179.983 ENERGY OUT = 179.264(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.323 ENERGY OUT = 180.087(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.08701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.087 ENERGY OUT = 179.368(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.423 ENERGY OUT = 180.191(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.19099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.191 ENERGY OUT = 179.473(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.523 ENERGY OUT = 180.294(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.29401 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.294 ENERGY OUT = 179.576(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.623 ENERGY OUT = 180.398(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.39799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.398 ENERGY OUT = 179.680(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.723 ENERGY OUT = 180.502(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.50200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.502 ENERGY OUT = 179.785(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.823 ENERGY OUT = 180.606(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.60600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.606 ENERGY OUT = 179.889(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 188.923 ENERGY OUT = 180.710(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.71001 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.710 ENERGY OUT = 179.994(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.023 ENERGY OUT = 180.813(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.81300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.813 ENERGY OUT = 180.097(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.123 ENERGY OUT = 180.917(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 180.91701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 180.917 ENERGY OUT = 180.201(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.223 ENERGY OUT = 181.021(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.02100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.021 ENERGY OUT = 180.306(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.323 ENERGY OUT = 181.125(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.12500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.125 ENERGY OUT = 180.410(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.423 ENERGY OUT = 181.229(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.22900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.229 ENERGY OUT = 180.514(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.523 ENERGY OUT = 181.333(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.33299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.333 ENERGY OUT = 180.619(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.623 ENERGY OUT = 181.436(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.43600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.436 ENERGY OUT = 180.722(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.723 ENERGY OUT = 181.540(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.53999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.540 ENERGY OUT = 180.826(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.823 ENERGY OUT = 181.644(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.64400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.644 ENERGY OUT = 180.931(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 189.923 ENERGY OUT = 181.748(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.74800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.748 ENERGY OUT = 181.035(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.023 ENERGY OUT = 181.851(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.85100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.851 ENERGY OUT = 181.138(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.123 ENERGY OUT = 181.955(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 181.95500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 181.955 ENERGY OUT = 181.243(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.223 ENERGY OUT = 182.059(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.05901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.059 ENERGY OUT = 181.347(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.323 ENERGY OUT = 182.163(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.16299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.163 ENERGY OUT = 181.451(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.423 ENERGY OUT = 182.267(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.26700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.267 ENERGY OUT = 181.556(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.523 ENERGY OUT = 182.370(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.37000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.370 ENERGY OUT = 181.659(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.623 ENERGY OUT = 182.474(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.47400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.474 ENERGY OUT = 181.763(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.723 ENERGY OUT = 182.578(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.57800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.578 ENERGY OUT = 181.868(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.823 ENERGY OUT = 182.682(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.68201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.682 ENERGY OUT = 181.972(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 190.923 ENERGY OUT = 182.785(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.78500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.785 ENERGY OUT = 182.075(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.023 ENERGY OUT = 182.889(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.88901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.889 ENERGY OUT = 182.180(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.123 ENERGY OUT = 182.993(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 182.99300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 182.993 ENERGY OUT = 182.284(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.223 ENERGY OUT = 183.097(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.09700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.097 ENERGY OUT = 182.388(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.323 ENERGY OUT = 183.200(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.20000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.200 ENERGY OUT = 182.492(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.423 ENERGY OUT = 183.304(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.30400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.304 ENERGY OUT = 182.596(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.523 ENERGY OUT = 183.408(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.40800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.408 ENERGY OUT = 182.700(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.623 ENERGY OUT = 183.511(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.51100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.511 ENERGY OUT = 182.804(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.723 ENERGY OUT = 183.615(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.61501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.615 ENERGY OUT = 182.908(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.823 ENERGY OUT = 183.719(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.71899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.719 ENERGY OUT = 183.012(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 191.923 ENERGY OUT = 183.823(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.823 ENERGY OUT = 183.117(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.023 ENERGY OUT = 183.926(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 183.92599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 183.926 ENERGY OUT = 183.220(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.123 ENERGY OUT = 184.030(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.03000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.030 ENERGY OUT = 183.324(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.223 ENERGY OUT = 184.134(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.13400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.134 ENERGY OUT = 183.429(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.323 ENERGY OUT = 184.237(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.23700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.237 ENERGY OUT = 183.532(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.423 ENERGY OUT = 184.341(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.34100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.341 ENERGY OUT = 183.636(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.523 ENERGY OUT = 184.445(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.44501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.445 ENERGY OUT = 183.741(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.623 ENERGY OUT = 184.548(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.54800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.548 ENERGY OUT = 183.844(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.723 ENERGY OUT = 184.652(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.65199 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.652 ENERGY OUT = 183.948(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.823 ENERGY OUT = 184.756(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.75600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.756 ENERGY OUT = 184.053(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 192.923 ENERGY OUT = 184.859(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.85899 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.859 ENERGY OUT = 184.156(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.023 ENERGY OUT = 184.963(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 184.96300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 32 STEPS ENERGY IN = 184.963 ENERGY OUT = 184.260(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.123 ENERGY OUT = 185.067(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.06700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.067 ENERGY OUT = 184.365(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.223 ENERGY OUT = 185.170(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.17000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.170 ENERGY OUT = 184.468(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.323 ENERGY OUT = 185.274(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.27400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.274 ENERGY OUT = 184.573(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.423 ENERGY OUT = 185.378(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.37801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.378 ENERGY OUT = 184.677(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.523 ENERGY OUT = 185.481(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.48100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.481 ENERGY OUT = 184.780(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.623 ENERGY OUT = 185.585(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.58501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.585 ENERGY OUT = 184.884(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.723 ENERGY OUT = 185.689(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.68900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.689 ENERGY OUT = 184.989(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.823 ENERGY OUT = 185.792(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.79201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.792 ENERGY OUT = 185.092(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 193.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 193.923 ENERGY OUT = 185.896(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 185.89600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 185.896 ENERGY OUT = 185.196(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.023 ENERGY OUT = 186.000(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.00000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.000 ENERGY OUT = 185.301(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.123 ENERGY OUT = 186.103(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.10300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.103 ENERGY OUT = 185.404(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.223 ENERGY OUT = 186.207(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.20700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.207 ENERGY OUT = 185.508(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.323 ENERGY OUT = 186.310(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.31000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.310 ENERGY OUT = 185.612(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.423 ENERGY OUT = 186.414(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.41400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.414 ENERGY OUT = 185.716(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.523 ENERGY OUT = 186.518(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.51801 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.518 ENERGY OUT = 185.820(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.623 ENERGY OUT = 186.621(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.62100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.621 ENERGY OUT = 185.924(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.723 ENERGY OUT = 186.725(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.72501 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.725 ENERGY OUT = 186.028(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.823 ENERGY OUT = 186.828(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.82800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.828 ENERGY OUT = 186.131(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 194.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 194.923 ENERGY OUT = 186.932(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 186.93201 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 186.932 ENERGY OUT = 186.236(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.023 ENERGY OUT = 187.036(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.03600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.036 ENERGY OUT = 186.340(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.123 ENERGY OUT = 187.139(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.13901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.139 ENERGY OUT = 186.443(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.223 ENERGY OUT = 187.243(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.24300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.243 ENERGY OUT = 186.548(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.323 ENERGY OUT = 187.346(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.34599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.346 ENERGY OUT = 186.651(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.423 ENERGY OUT = 187.450(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.45000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.450 ENERGY OUT = 186.755(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.523 ENERGY OUT = 187.554(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.55400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.554 ENERGY OUT = 186.860(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.623 ENERGY OUT = 187.657(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.65700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.657 ENERGY OUT = 186.963(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.723 ENERGY OUT = 187.761(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.76100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.761 ENERGY OUT = 187.067(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.823 ENERGY OUT = 187.864(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.86400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.864 ENERGY OUT = 187.171(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 195.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 195.923 ENERGY OUT = 187.968(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 187.96800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 187.968 ENERGY OUT = 187.275(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.023 ENERGY OUT = 188.071(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.07100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.071 ENERGY OUT = 187.378(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.123 ENERGY OUT = 188.175(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.17500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.175 ENERGY OUT = 187.483(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.223 ENERGY OUT = 188.279(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.27901 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.279 ENERGY OUT = 187.587(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.323 ENERGY OUT = 188.382(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.38200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.382 ENERGY OUT = 187.690(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.423 ENERGY OUT = 188.486(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.48599 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.486 ENERGY OUT = 187.795(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.523 ENERGY OUT = 188.589(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.58900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.589 ENERGY OUT = 187.898(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.623 ENERGY OUT = 188.693(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.69299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.693 ENERGY OUT = 188.002(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.723 ENERGY OUT = 188.796(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.79601 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.796 ENERGY OUT = 188.106(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.823 ENERGY OUT = 188.900(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 188.89999 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 188.900 ENERGY OUT = 188.210(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 196.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 196.923 ENERGY OUT = 189.003(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.00301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.003 ENERGY OUT = 188.313(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.023 ENERGY OUT = 189.107(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.10699 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.107 ENERGY OUT = 188.418(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.123 ENERGY OUT = 189.210(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.21001 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.210 ENERGY OUT = 188.521(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.223 ENERGY OUT = 189.314(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.31400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.314 ENERGY OUT = 188.625(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.323 ENERGY OUT = 189.417(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.41701 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.417 ENERGY OUT = 188.729(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.423 ENERGY OUT = 189.521(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.52100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.521 ENERGY OUT = 188.833(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.523 ENERGY OUT = 189.624(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.62399 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.624 ENERGY OUT = 188.936(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.623 ENERGY OUT = 189.728(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.72800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.728 ENERGY OUT = 189.040(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.723 ENERGY OUT = 189.831(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.83099 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.831 ENERGY OUT = 189.144(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.823 ENERGY OUT = 189.935(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 189.93500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 189.935 ENERGY OUT = 189.248(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 197.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 197.923 ENERGY OUT = 190.038(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.03799 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.038 ENERGY OUT = 189.351(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.023 ENERGY OUT = 190.142(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.14200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.142 ENERGY OUT = 189.456(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.123 ENERGY OUT = 190.245(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.24500 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.245 ENERGY OUT = 189.559(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.223 ENERGY OUT = 190.349(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.34900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.349 ENERGY OUT = 189.663(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.323 ENERGY OUT = 190.452(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.45200 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.452 ENERGY OUT = 189.767(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.423 ENERGY OUT = 190.556(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.55600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.556 ENERGY OUT = 189.871(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.523 ENERGY OUT = 190.659(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.65900 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.659 ENERGY OUT = 189.974(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.623 ENERGY OUT = 190.763(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.76300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.763 ENERGY OUT = 190.079(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.723 ENERGY OUT = 190.866(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.86600 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.866 ENERGY OUT = 190.182(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.823 ENERGY OUT = 190.970(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 190.97000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 190.970 ENERGY OUT = 190.286(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 198.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 198.923 ENERGY OUT = 191.073(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.07300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.073 ENERGY OUT = 190.390(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.02299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.023 ENERGY OUT = 191.177(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.17700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.177 ENERGY OUT = 190.494(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.12300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.123 ENERGY OUT = 191.280(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.28000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.280 ENERGY OUT = 190.597(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.22301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.223 ENERGY OUT = 191.383(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.38300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.383 ENERGY OUT = 190.701(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.32300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.323 ENERGY OUT = 191.487(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.48700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.487 ENERGY OUT = 190.805(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.42300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.423 ENERGY OUT = 191.590(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.59000 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.590 ENERGY OUT = 190.908(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.52299 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.523 ENERGY OUT = 191.694(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.69400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.694 ENERGY OUT = 191.012(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.62300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.623 ENERGY OUT = 191.797(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.79700 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.797 ENERGY OUT = 191.116(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.72301 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.723 ENERGY OUT = 191.901(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 191.90100 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 191.901 ENERGY OUT = 191.220(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.82300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.823 ENERGY OUT = 192.004(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.00400 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 192.004 ENERGY OUT = 191.323(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 199.92300 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2562E+03 + THICKNESS = 0.1100E+00 CM OR 0.4331E-01 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.25619E+03 MG/CMSQ + CALC IN- 256 STEPS ENERGY IN = 199.923 ENERGY OUT = 192.108(MEV) + + + + + + + PASSAGE OF CHARGED PARTICLE THROUGH ABSORBER SANDWICH + + + + AP = 3. ZP = 2. INITIAL ENERGY = 192.10800 + + + ABSORBER SANDWICH CONTAINS - 1 LAYERS + + + + + LAYER # 1 - SOLID ABSORBER - AREAL DENSITY = 0.2189E+02 + THICKNESS = 0.9400E-02 CM OR 0.3701E-02 INCH DENSITY = 0.233E+01 G/CM3 + A = 28. Z = 14. AREAL DENSITY (PARTIAL) = 0.21893E+02 MG/CMSQ + CALC IN- 16 STEPS ENERGY IN = 192.108 ENERGY OUT = 191.428(MEV) diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/filtered.out b/anasen_analysis_vignesh/eloss_calculations/stopit/filtered.out new file mode 100644 index 0000000..39c20fa --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/filtered.out @@ -0,0 +1,6 @@ +Charged particle has Z = 2. A = 4. Initialenergy = 0.132 MeV. +Energy lost in layer = 0.132 MeV +Energy remaining = 0.000 MeV +Charged particle has Z = 2. A = 4. Initialenergy = 10.132 MeV. +Energy lost in layer = 10.133 MeV +Energy remaining = 0.000 MeV diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/outfile.out b/anasen_analysis_vignesh/eloss_calculations/stopit/outfile.out new file mode 100644 index 0000000..bb48deb --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/outfile.out @@ -0,0 +1,50 @@ +4 4 + + +Charged particle has Z = 2. A = 4. Initialenergy = 0.132 MeV. + + +Absorber contains 1 layers. + + +Layer # 1 - Solid Absorber +Density = 0.2329E+01 g/cm3 Thickness = 0.2329E+02 mg/cm2 +Z = 14. A = 28. Atoms per molecule = 1. +Energy lost in layer = 0.132 MeV + +Energy remaining = 0.000 MeV + +Output also written to stopit.log + + 1 define stopee + 2 define absorber + 3 edit absorber + 4 run with current parameters + 5 find thickness of absorber to stop the stopee + 6 print status of data + 7 stop +4 4 + + +Charged particle has Z = 2. A = 4. Initialenergy = 10.132 MeV. + + +Absorber contains 1 layers. + + +Layer # 1 - Solid Absorber +Density = 0.2329E+01 g/cm3 Thickness = 0.2329E+02 mg/cm2 +Z = 14. A = 28. Atoms per molecule = 1. +Energy lost in layer = 10.133 MeV + +Energy remaining = 0.000 MeV + +Output also written to stopit.log + + 1 define stopee + 2 define absorber + 3 edit absorber + 4 run with current parameters + 5 find thickness of absorber to stop the stopee + 6 print status of data + 7 stop diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/script.exp b/anasen_analysis_vignesh/eloss_calculations/stopit/script.exp new file mode 100755 index 0000000..e1b67cf --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/script.exp @@ -0,0 +1,106 @@ +#!/usr/bin/expect -f +# +set timeout -1 +spawn ./a.out +match_max 100000 +expect -exact "\r + 1 define stopee\r + 2 define absorber\r + 3 edit absorber\r + 4 run with current parameters\r + 5 find thickness of absorber to stop the stopee\r + 6 print status of data\r + 7 stop\r +" +send -- "1\r" +expect -exact "1\r + Enter Z and A of stopee.\r +" +send -- "2\r" +expect -exact "2\r +" +send -- "4\r" +expect -exact "4\r + Enter energy in MeV.\r +" +send -- "5.486\r" +expect -exact "5.486\r +\r + 1 define stopee\r + 2 define absorber\r + 3 edit absorber\r + 4 run with current parameters\r + 5 find thickness of absorber to stop the stopee\r + 6 print status of data\r + 7 stop\r +" +send -- "2\r" +expect -exact "2\r +\r + How many stopping layers are there in the absorber?\r +" +send -- "1\r" +expect -exact "1\r +\r +Is layer 1 a solid, gas, or standardized medium?\r +(0 = solid, 1 = gas, 2 = standardized medium)\r +(Standardized media are: CO2, Si, C \[graphite\], C4H10, CF4,\r +CH2, CD2, He, and H2)\r +" +send -- "2\r" +expect -exact "2\r +Which standardized medium for layer 1?\r +1: CO2\r +2: Si\r +3: C (graphite)\r +4: C4H10\r +5: CF4\r +6: CH2\r +7: CD2\r +8: He-gas\r +9: H2-gas\r +" +send -- "2\r" +expect -exact "2\r +Enter thickness(microns) for layer 1\r +" +send -- "100\r" +expect -exact "100\r +\r + 1 define stopee\r + 2 define absorber\r + 3 edit absorber\r + 4 run with current parameters\r + 5 find thickness of absorber to stop the stopee\r + 6 print status of data\r + 7 stop\r +" +send -- "4\r" +expect -exact "4\r +\r +\r +Charged particle has Z = 2. A = 4. Initialenergy = 5.486 MeV.\r +\r +\r +Absorber contains 1 layers.\r +\r +\r +Layer # 1 - Solid Absorber\r +Density = 0.2329E+01 g/cm3 Thickness = 0.2329E+02 mg/cm2\r +Z = 14. A = 28. Atoms per molecule = 1.\r +Energy lost in layer = 5.486 MeV\r +\r +Energy remaining = 0.000 MeV\r +\r +Output also written to stopit.log\r +\r + 1 define stopee\r + 2 define absorber\r + 3 edit absorber\r + 4 run with current parameters\r + 5 find thickness of absorber to stop the stopee\r + 6 print status of data\r + 7 stop\r +" +send -- "7\r" +expect eof diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/stopit.expect b/anasen_analysis_vignesh/eloss_calculations/stopit/stopit.expect new file mode 100755 index 0000000..927c03b --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/stopit.expect @@ -0,0 +1,106 @@ +#!/usr/bin/expect -f +# +# This Expect script was generated by autoexpect on Sat Jan 31 17:06:49 2026 +# Expect and autoexpect were both written by Don Libes, NIST. +# +# Note that autoexpect does not guarantee a working script. It +# necessarily has to guess about certain things. Two reasons a script +# might fail are: +# +# 1) timing - A surprising number of programs (rn, ksh, zsh, telnet, +# etc.) and devices discard or ignore keystrokes that arrive "too +# quickly" after prompts. If you find your new script hanging up at +# one spot, try adding a short sleep just before the previous send. +# Setting "force_conservative" to 1 (see below) makes Expect do this +# automatically - pausing briefly before sending each character. This +# pacifies every program I know of. The -c flag makes the script do +# this in the first place. The -C flag allows you to define a +# character to toggle this mode off and on. + +set force_conservative 0 ;# set to 1 to force conservative mode even if + ;# script wasn't run conservatively originally +if {$force_conservative} { + set send_slow {1 .1} + proc send {ignore arg} { + sleep .1 + exp_send -s -- $arg + } +} + +# +# 2) differing output - Some programs produce different output each time +# they run. The "date" command is an obvious example. Another is +# ftp, if it produces throughput statistics at the end of a file +# transfer. If this causes a problem, delete these patterns or replace +# them with wildcards. An alternative is to use the -p flag (for +# "prompt") which makes Expect only look for the last line of output +# (i.e., the prompt). The -P flag allows you to define a character to +# toggle this mode off and on. +# +# Read the man page for more info. +# +# -Don + + +set timeout -1 +spawn ./a.out +match_max 100000 +expect "* 7 stop\r +" +send -- "1\r" +expect -exact "1\r + Enter Z and A of stopee.\r +" +send -- "4" +expect -exact " " +send -- "2\r" +expect -exact "2\r +" +send -- "4\r" +expect -exact "4\r + Enter energy in MeV.\r +" +send -- "5.486\r" +expect -exact "5.486\r +\r + 1 define stopee\r + 2 define absorber\r + 3 edit absorber\r + 4 run with current parameters\r + 5 find thickness of absorber to stop the stopee\r + 6 print status of data\r + 7 stop\r +" +send -- "2\r" + +expect "*How many stopping layers are there in the absorber?\r" +send -- "1\r" + +expect "*CH2, CD2, He, and H2)\r" +send -- "2\r" + +expect "*Which standardized medium for layer 1?\r +1: CO2\r +2: Si\r +3: C (graphite)\r +4: C4H10\r +5: CF4\r +6: CH2\r +7: CD2\r +8: He-gas\r +9: H2-gas\r +" +send -- "2\r" +expect " +* Enter thickness(microns) for layer 1\r +" +send -- "100\r" +expect " +* 7 stop\r +" +send -- "4\r" +expect " +* 7 stop\r +" +send -- "7\r" +expect eof diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/stopit2.for b/anasen_analysis_vignesh/eloss_calculations/stopit/stopit2.for new file mode 100755 index 0000000..be1d2d4 --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/stopit2.for @@ -0,0 +1,1057 @@ + PROGRAM stopit + +C +C PROGRAM DESCRIPTION: +C +C Program calculates energy loss in absorber sandwich. Uses energy +C routine "absorb.for" obtained from Dan Shapira who obtained it from +C somebody in Germany. I don't know - it works! +C +C +C The the program can be compiled using the command +C g77 stopit.for desorb.for -o stopit +C or, for more recent compilers +C gfortran stopit.for desorb.for -o stopit + +c +c +C +C AUTHORS: +C +C Dan Bardayan +C Jonathan Wheeler +C Patrick O'Malleyst +C S.D. Pain +C +C CREATION DATE: 12/23/97 +C +C +C C H A N G E L O G +C +C Date | Name | Description +C ----------------+------------------+----------------------------------------- +C 12/23/97 | Dan Bardayan | Creation of the program +C 10/03/03 | Dan Bardayan | Modified to compile w/ g77 +C 05/27/11 | Jonathan Wheeler| Modified to include standardized media +C | | and to find the thickness required to +C | | stop a "stopee" +C 6/4/2020 | S.D. Pain | Modified to correct unset molar +C | | concentration of second element in +C | | gas layers for standard materials +C | | Corrected CD2 density from 0.93 to 1.063 g/cm3 +C ----------------+------------------+----------------------------------------- +C ----------------+------------------+----------------------------------------- +C + IMPLICIT NONE + + INTEGER i, j, k,imm, ism, iedit, issm + integer ianz, ianzi, ianzide + integer isg,inn + integer stdm, siupb, soupb, gaupb + +c stdm: index for standard media + +c imm: which main menu item we are on +c ism: which sub menu item we are on +c iedit: which layer to edit +c ianz : # of energy loss layers +c ianzi : index of last layer in which the energy of the pariticle +c is not recorded - don't blame me for this vague description +c i got it straight from desorb.for- i always set it to 2 +c ianzide : element # for DE calculation- i always set it to 1 +c isg(i): 0,1-0 means ith layer is solid,1 means ith layer is gas +c inn(i): no. of elements in ith layer + +c sithk: thickness in microns of standard silicon +c tethk: test thickness for iteration purposes +c error: error in iteration thickness for bisection method + + + real den, thk,prs,xln,elnum,concn + real anumb, znumb + real arden, prden, prthk + real z, a, energy, loste(19),zp, edep + real sithk, tethk, error + +c z : proton number of stopee +c a : mass number of stopee +c energy: energy of stopee in MeV +c den(i) : density (g/cm3) of ith layer-only for solid +c thk(i): thickness (mg/cm3) of ith layer-only for solid +c prs(i): pressure (torr) of ith layer-only for gas +c xln(i): thickness (cm) of ith layer-only for gas +c elnum(i,j):# atoms of jth element in ith layer per molecule +c concn(i,j): concentration(molar) j element in ith layer = 1 usually +c anumb(i,j): atomic mass in amu for j element in ith layer +c znumb(i,j): atomic no. for jth element in ith layer +c loste(i):energy lost in ith layer +c edep: energy deposited in absorber = sum(loste) + + COMMON ISG(19),INN(19) + + ,DEN(19),THK(19),PRS(19),XLN(19),ARDEN(19) + + ,ZNUMB(19,4),ANUMB(19,4),ELNUM(19,4),CONCN(19,4) + + ,PRDEN(19,4),PRTHK(19,4) + + + open(unit=7,file='stopit.log',status='unknown') + +c define some initial values in case the program is run before all the +c important parameters are defined + + ianz = 1 + ianzi = 2 + ianzide = 1 + isg(1) = 1 + inn(1) = 1 + stdm = 1 + sithk = 10. + z = 1. + a = 1. + energy = 10. + den(1) = 1.0 + thk(1) = 0.1 + prs(1) = 10. + xln(1) = 10. + elnum(1,1) = 1. + concn(1,1) = 1. + anumb(1,1) = 12. + znumb(1,1) = 6. + +c For finding thicknesses, upper bounds need to be set. +c Silicon upper bound in microns + siupb = 1500 +c Other solids' upper bound in mg/cm2 + soupb = 1000 +c Gas upper bound in cm + gaupb = 100 + +c This is the control portion of the program + +10 write(6,15) +15 format(/' 1 define stopee'/ + * ' 2 define absorber'/ + * ' 3 edit absorber'/ + * ' 4 run with current parameters'/ + * ' 5 find thickness of absorber to stop the stopee'/ + * ' 6 print status of data'/ + * ' 7 stop') + read(5,*)imm + + if(imm.eq.1)then + goto 100 + elseif(imm.eq.2)then + goto 200 + elseif(imm.eq.3)then + goto 300 + elseif(imm.eq.4)then + goto 400 +c This section was editted to add a new function, it's easier to +c have a discontinuity in labels than to relabel everything. + elseif(imm.eq.5)then + goto 600 + elseif(imm.eq.6)then + goto 500 + elseif(imm.eq.7)then + goto 1000 + else + goto 10 + endif + +c Define stopee +100 write(6,*)'Enter Z and A of stopee.' + read(5,*)z,a + write(6,*)'Enter energy in MeV.' + read(5,*)energy + goto 10 + +c Define absorber +200 write(6,*) + write(6,*)'How many stopping layers are there in the absorber?' + read(5,*)ianz + + do i = 1, ianz +201 write(6,210)i + read(5,*)isg(i) + + if(isg(i).eq.0)then + write(6,220)i + read(5,*)den(i),thk(i) + elseif(isg(i).eq.1)then + write(6,230)i + read(5,*)prs(i),xln(i) + elseif(isg(i).eq.2)then + write(6,260)i + read(5,*)stdm + if(stdm.eq.1)then + write(6,230)i + read(5,*)prs(i),xln(i) +c CO2 standardized medium + isg(i) = 1 + inn(i) = 2 + znumb(i,1)=6 + znumb(i,2)=8 + anumb(i,1)=12 + anumb(i,2)=16 + elnum(i,1)=1 + elnum(i,2)=2 + concn(i,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(i,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 202 + elseif(stdm.eq.2)then + write(6,221)i + read(5,*)sithk +c Si standardized medium + isg(i) = 0 + den(i) = 2.329 + thk(i) = 0.2329*sithk + inn(i) = 1 + znumb(i,1)=14 + anumb(i,1)=28 + elnum(i,1)=1 + goto 202 + elseif(stdm.eq.3)then + write(6,222)i + read(5,*)thk(i) +c C (graphite) standardized medium + isg(i) = 0 + den(i) = 2.267 + inn(i) = 1 + znumb(i,1)=6 + anumb(i,1)=12 + elnum(i,1)=1 + goto 202 + elseif(stdm.eq.4)then + write(6,230)i + read(5,*)prs(i),xln(i) +c C4H10 standardized medium + isg(i) = 1 + inn(i) = 2 + znumb(i,1)=6.0 + znumb(i,2)=1.0 + anumb(i,1)=12.0 + anumb(i,2)=1.0 + elnum(i,1)=4.0 + elnum(i,2)=10.0 + concn(i,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(i,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 202 + elseif(stdm.eq.5)then + write(6,230)i + read(5,*)prs(i),xln(i) +c CF4 standardized medium + isg(i) = 1 + inn(i) = 2 + znumb(i,1)=6 + znumb(i,2)=9 + anumb(i,1)=12 + anumb(i,2)=19 + elnum(i,1)=1 + elnum(i,2)=4 + concn(i,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(i,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 202 + elseif(stdm.eq.6)then + write(6,222)i + read(5,*)thk(i) +c CH2 standardized medium + isg(i) = 0 + inn(i) = 2 + den(i) = 0.94 + znumb(i,1)=6 + znumb(i,2)=1 + anumb(i,1)=12 + anumb(i,2)=1 + elnum(i,1)=1 + elnum(i,2)=2 + goto 202 + elseif(stdm.eq.7)then + write(6,222)i + read(5,*)thk(i) +c CD2 standardized medium + isg(i) = 0 + inn(i) = 2 + den(i) = 1.063 !Changed 6/4/2020 by SDP to correct CD2 density from 0.93 + znumb(i,1)=6 + znumb(i,2)=1 + anumb(i,1)=12 + anumb(i,2)=2 + elnum(i,1)=1 + elnum(i,2)=2 + goto 202 + elseif(stdm.eq.8)then + write(6,230)i + read(5,*)prs(i),xln(i) +c helium gas standardized medium + isg(i) = 1 + inn(i) = 1 + znumb(i,1)=2 + anumb(i,1)=4 + elnum(i,1)=1 + concn(i,1)=1 !Added 6/4/2020 by SDP for explicit completeness + goto 202 + elseif(stdm.eq.9)then + write(6,230)i + read(5,*)prs(i),xln(i) +c hydrogen gas standardized medium + isg(i) = 1 + inn(i) = 1 + znumb(i,1)=1 + anumb(i,1)=1 + elnum(i,1)=2 + concn(i,1)=1 !Added 6/4/2020 by SDP for explicit completeness + goto 202 + else + goto 201 + endif + else + goto 201 + endif + + write(6,240)i + read(5,*)inn(i) + + do j = 1, inn(i) + write(6,250)i,j + read(5,*)znumb(i,j),anumb(i,j), elnum(i,j) + concn(i,j)=1. + enddo + +202 j = 1 + + enddo + + goto 10 + +210 format(/'Is layer ',I2,' a solid, gas, or standardized medium?', + +/'(0 = solid, 1 = gas, 2 = standardized medium)', + +/'(Standardized media are: CO2, Si, C [graphite], C4H10, CF4,', + +/'CH2, CD2, He, and H2)') +220 format('Enter density(g/cm3) and thickness(mg/cm2) for layer ',I2) +221 format('Enter thickness(microns) for layer ',I2) +222 format('Enter thickness(mg/cm2) for layer ',I2) +230 format('Enter pressure(Torr) and length(cm) for layer ',I2) +240 format('How many elements are in layer ', I2 ,'?') +250 format('For layer ',I2,' ,element ',I2,' - enter Z, A, and the + + number of atoms per molecule. ') +260 format('Which standardized medium for layer ', I2, '?', + +/'1: CO2', + +/'2: Si', + +/'3: C (graphite)', + +/'4: C4H10', + +/'5: CF4', + +/'6: CH2', + +/'7: CD2', + +/'8: He-gas', + +/'9: H2-gas') + +c Edit absorber +300 write(6,301) + read(5,*)ism +301 format(/' 1 edit layer'/ + * ' 2 add layer onto end of absorber'/ + * ' 3 add new layer in front of absorber'/ + * ' 4 return to main menu') + + if(ism.eq.1)then + goto 310 + elseif(ism.eq.2)then + goto 340 + elseif(ism.eq.3)then + goto 360 + elseif(ism.eq.4)then + goto 10 + else + goto 300 + endif + +c Edit layer +310 write(6,311) + read(5,*)iedit +311 format(/'Which layer would you like to edit?') + +312 write(6,313) + read(5,*)issm +313 format(/' 1 change state, density, thickness, etc...'/ + * ' 2 change elemental composition'/ + * ' 3 go back to previous menu'/) + + if(issm.eq.1)then + goto 315 + elseif(issm.eq.2)then + goto 320 + elseif(issm.eq.3)then + goto 300 + else + goto 312 + endif + +315 write(6,210)iedit + read(5,*)isg(iedit) + + if(isg(iedit).eq.0)then + write(6,220)iedit + read(5,*)den(iedit),thk(iedit) + elseif(isg(iedit).eq.1)then + write(6,230)iedit + read(5,*)prs(iedit),xln(iedit) + elseif(isg(iedit).eq.2)then + write(6,260)iedit + read(5,*)stdm + if(stdm.eq.1)then + write(6,230)iedit + read(5,*)prs(iedit),xln(iedit) +c CO2 standardized medium + isg(iedit) = 1 + inn(iedit) = 2 + znumb(iedit,1)=6 + znumb(iedit,2)=8 + anumb(iedit,1)=12 + anumb(iedit,2)=16 + elnum(iedit,1)=1 + elnum(iedit,2)=2 + concn(iedit,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(iedit,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 312 + elseif(stdm.eq.2)then + write(6,221)iedit + read(5,*)sithk +c Si standardized medium + isg(iedit) = 0 + den(iedit) = 2.329 + thk(iedit) = 0.2329*sithk + inn(iedit) = 1 + znumb(iedit,1)=14 + anumb(iedit,1)=28 + elnum(iedit,1)=1 + goto 312 + elseif(stdm.eq.3)then + write(6,222)iedit + read(5,*)thk(iedit) +c C (graphite) standardized medium + isg(iedit) = 0 + den(iedit) = 2.267 + inn(iedit) = 1 + znumb(iedit,1)=6 + anumb(iedit,1)=12 + elnum(iedit,1)=1 + goto 312 + elseif(stdm.eq.4)then + write(6,230)iedit + read(5,*)prs(iedit),xln(iedit) +c C4H10 standardized medium + isg(iedit) = 1 + inn(iedit) = 2 + znumb(iedit,1)=6 + znumb(iedit,2)=1 + anumb(iedit,1)=12 + anumb(iedit,2)=1 + elnum(iedit,1)=4 + elnum(iedit,2)=10 + concn(iedit,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(iedit,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 312 + elseif(stdm.eq.5)then + write(6,230)iedit + read(5,*)prs(iedit),xln(iedit) +c CF4 standardized medium + isg(iedit) = 1 + inn(iedit) = 2 + znumb(iedit,1)=6 + znumb(iedit,2)=9 + anumb(iedit,1)=12 + anumb(iedit,2)=19 + elnum(iedit,1)=1 + elnum(iedit,2)=4 + concn(iedit,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(iedit,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 312 + elseif(stdm.eq.6)then + write(6,222)iedit + read(5,*)thk(iedit) +c CH2 standardized medium + isg(iedit) = 0 + inn(iedit) = 2 + den(iedit) = 0.94 + znumb(iedit,1)=6 + znumb(iedit,2)=1 + anumb(iedit,1)=12 + anumb(iedit,2)=1 + elnum(iedit,1)=1 + elnum(iedit,2)=2 + goto 312 + elseif(stdm.eq.7)then + write(6,222)iedit + read(5,*)thk(iedit) +c CD2 standardized medium + isg(iedit) = 0 + inn(iedit) = 2 + den(iedit) = 1.063 !Changed 6/4/2020 by SDP to correct CD2 density from 0.93 + znumb(iedit,1)=6 + znumb(iedit,2)=1 + anumb(iedit,1)=12 + anumb(iedit,2)=2 + elnum(iedit,1)=1 + elnum(iedit,2)=2 + goto 312 + elseif(stdm.eq.8)then + write(6,230)iedit + read(5,*)prs(iedit),xln(iedit) +c helium gas standardized medium + isg(iedit) = 1 + inn(iedit) = 1 + znumb(iedit,1)=2 + anumb(iedit,1)=4 + elnum(iedit,1)=1 + concn(iedit,1)=1 !Added 6/4/2020 by SDP for explicit completeness + elseif(stdm.eq.9)then + write(6,230)iedit + read(5,*)prs(iedit),xln(iedit) +c hydrogen gas standardized medium + isg(iedit) = 1 + inn(iedit) = 1 + znumb(iedit,1)=1 + anumb(iedit,1)=1 + elnum(iedit,1)=2 + concn(iedit,1)=1 !Added 6/4/2020 by SDP for explicit completeness + else + goto 315 + endif + else + goto 315 + endif + + goto 312 + +320 write(6,240)iedit + read(5,*)inn(iedit) + + do j = 1, inn(iedit) + write(6,250)iedit,j + read(5,*)znumb(iedit,j),anumb(iedit,j), elnum(iedit,j) + concn(iedit,j)=1. + enddo + + goto 312 + +c Add layer onto end +340 ianz = ianz + 1 + +345 write(6,210)ianz + read(5,*)isg(ianz) + + if(isg(ianz).eq.0)then + write(6,220)ianz + read(5,*)den(ianz),thk(ianz) + elseif(isg(ianz).eq.1)then + write(6,230)ianz + read(5,*)prs(ianz),xln(ianz) + elseif(isg(ianz).eq.2)then + write(6,260)ianz + read(5,*)stdm + if(stdm.eq.1)then + write(6,230)ianz + read(5,*)prs(ianz),xln(ianz) +c CO2 standardized medium + isg(ianz) = 1 + inn(ianz) = 2 + znumb(ianz,1)=6 + znumb(ianz,2)=8 + anumb(ianz,1)=12 + anumb(ianz,2)=16 + elnum(ianz,1)=1 + elnum(ianz,2)=2 + concn(ianz,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(ianz,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 300 + elseif(stdm.eq.2)then + write(6,221)ianz + read(5,*)sithk +c Si standardized medium + isg(ianz) = 0 + den(ianz) = 2.329 + thk(ianz) = 0.2329*sithk + inn(ianz) = 1 + znumb(ianz,1)=14 + anumb(ianz,1)=28 + elnum(ianz,1)=1 + goto 300 + elseif(stdm.eq.3)then + write(6,222)ianz + read(5,*)thk(ianz) +c C (graphite) standardized medium + isg(ianz) = 0 + den(ianz) = 2.267 + inn(ianz) = 1 + znumb(ianz,1)=6 + anumb(ianz,1)=12 + elnum(ianz,1)=1 + goto 300 + elseif(stdm.eq.4)then + write(6,230)ianz + read(5,*)prs(ianz),xln(ianz) +c C4H10 standardized medium + isg(ianz) = 1 + inn(ianz) = 2 + znumb(ianz,1)=6 + znumb(ianz,2)=1 + anumb(ianz,1)=12 + anumb(ianz,2)=1 + elnum(ianz,1)=4 + elnum(ianz,2)=10 + concn(ianz,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(ianz,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 300 + elseif(stdm.eq.5)then + write(6,230)ianz + read(5,*)prs(ianz),xln(ianz) +c CF4 standardized medium + isg(ianz) = 1 + inn(ianz) = 2 + znumb(ianz,1)=6 + znumb(ianz,2)=9 + anumb(ianz,1)=12 + anumb(ianz,2)=19 + elnum(ianz,1)=1 + elnum(ianz,2)=4 + concn(ianz,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(ianz,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 300 + elseif(stdm.eq.6)then + write(6,222)ianz + read(5,*)thk(ianz) +c CH2 standardized medium + isg(ianz) = 0 + inn(ianz) = 2 + den(ianz) = 0.94 + znumb(ianz,1)=6 + znumb(ianz,2)=1 + anumb(ianz,1)=12 + anumb(ianz,2)=1 + elnum(ianz,1)=1 + elnum(ianz,2)=2 + goto 300 + elseif(stdm.eq.7)then + write(6,222)ianz + read(5,*)thk(ianz) +c CD2 standardized medium + isg(ianz) = 0 + inn(ianz) = 2 + den(ianz) = 1.063 !Changed 6/4/2020 by SDP to correct CD2 density from 0.93 + znumb(ianz,1)=6 + znumb(ianz,2)=1 + anumb(ianz,1)=12 + anumb(ianz,2)=2 + elnum(ianz,1)=1 + elnum(ianz,2)=2 + goto 300 + elseif(stdm.eq.8)then + write(6,230)ianz + read(5,*)prs(ianz),xln(ianz) +c helium gas standardized medium + isg(ianz) = 1 + inn(ianz) = 1 + znumb(ianz,1)=2 + anumb(ianz,1)=4 + elnum(ianz,1)=1 + concn(ianz,1)=1 !Added 6/4/2020 by SDP for explicit completeness + elseif(stdm.eq.9)then + write(6,230)ianz + read(5,*)prs(ianz),xln(ianz) +c hydrogen gas standardized medium + isg(ianz) = 1 + inn(ianz) = 1 + znumb(ianz,1)=1 + anumb(ianz,1)=1 + elnum(ianz,1)=2 + concn(ianz,1)=1 !Added 6/4/2020 by SDP for explicit completeness + goto 300 + else + goto 345 + endif + else + goto 345 + endif + + write(6,240)ianz + read(5,*)inn(ianz) + + do j = 1, inn(ianz) + write(6,250)ianz,j + read(5,*)znumb(ianz,j),anumb(ianz,j), elnum(ianz,j) + concn(ianz,j)=1. + enddo + + goto 300 + +c Add new layer in front of absorber +360 ianz = ianz + 1 + + do j = ianz, 2, -1 + isg(j)=isg(j-1) + den(j)=den(j-1) + thk(j)=thk(j-1) + prs(j)=prs(j-1) + xln(j)=xln(j-1) + inn(j)=inn(j-1) + + do k = 1, inn(j) + znumb(j,k)=znumb(j-1,k) + anumb(j,k)=anumb(j-1,k) + elnum(j,k)=elnum(j-1,k) + concn(j,k)=concn(j-1,k) + enddo + + enddo + +365 write(6,210)1 + read(5,*)isg(1) + + if(isg(1).eq.0)then + write(6,220)1 + read(5,*)den(1),thk(1) + elseif(isg(1).eq.1)then + write(6,230)1 + read(5,*)prs(1),xln(1) + elseif(isg(1).eq.2)then + write(6,260)1 + read(5,*)stdm + if(stdm.eq.1)then + write(6,230)1 + read(5,*)prs(1),xln(1) +c CO2 standardized medium + isg(1) = 1 + inn(1) = 2 + znumb(1,1)=6 + znumb(1,2)=8 + anumb(1,1)=12 + anumb(1,2)=16 + elnum(1,1)=1 + elnum(1,2)=2 + concn(1,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(1,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 300 + elseif(stdm.eq.2)then + write(6,221)1 + read(5,*)sithk +c Si standardized medium + isg(1) = 0 + den(1) = 2.329 + thk(1) = 0.2329*sithk + inn(1) = 1 + znumb(1,1)=14 + anumb(1,1)=28 + elnum(1,1)=1 + goto 300 + elseif(stdm.eq.3)then + write(6,222)1 + read(5,*)thk(1) +c C (graphite) standardized medium + isg(1) = 0 + den(1) = 2.267 + inn(1) = 1 + znumb(1,1)=6 + anumb(1,1)=12 + elnum(1,1)=1 + goto 300 + elseif(stdm.eq.4)then + write(6,230)1 + read(5,*)prs(1),xln(1) +c C4H10 standardized medium + isg(1) = 1 + inn(1) = 2 + znumb(1,1)=6 + znumb(1,2)=1 + anumb(1,1)=12 + anumb(1,2)=1 + elnum(1,1)=4 + elnum(1,2)=10 + concn(1,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(1,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 300 + elseif(stdm.eq.5)then + write(6,230)1 + read(5,*)prs(1),xln(1) +c CF4 standardized medium + isg(1) = 1 + inn(1) = 2 + znumb(1,1)=6 + znumb(1,2)=9 + anumb(1,1)=12 + anumb(1,2)=19 + elnum(1,1)=1 + elnum(1,2)=4 + concn(1,1)=1 !Added 6/4/2020 by SDP for explicit completeness + concn(1,2)=1 !Added 6/4/2020 by SDP to fix bug where element 2 was not included correctly + goto 300 + elseif(stdm.eq.6)then + write(6,222)1 + read(5,*)thk(1) +c CH2 standardized medium + isg(1) = 0 + inn(1) = 2 + den(1) = 0.94 + znumb(1,1)=6 + znumb(1,2)=1 + anumb(1,1)=12 + anumb(1,2)=1 + elnum(1,1)=1 + elnum(1,2)=2 + goto 300 + elseif(stdm.eq.7)then + write(6,222)1 + read(5,*)thk(1) +c CD2 standardized medium + isg(1) = 0 + inn(1) = 2 + den(1) = 1.063 !Changed 6/4/2020 by SDP to correct CD2 density from 0.93 + znumb(1,1)=6 + znumb(1,2)=1 + anumb(1,1)=12 + anumb(1,2)=2 + elnum(1,1)=1 + elnum(1,2)=2 + goto 300 + elseif(stdm.eq.8)then + write(6,230)1 + read(5,*)prs(1),xln(1) +c helium gas standardized medium + isg(1) = 1 + inn(1) = 1 + znumb(1,1)=2 + anumb(1,1)=4 + elnum(1,1)=1 + concn(1,1)=1 !Added 6/4/2020 by SDP for explicit completeness + goto 300 + elseif(stdm.eq.9)then + write(6,230)1 + read(5,*)prs(1),xln(1) +c hydrogen gas standardized medium + isg(1) = 1 + inn(1) = 1 + znumb(1,1)=1 + anumb(1,1)=1 + elnum(1,1)=2 + concn(1,1)=1 !Added 6/4/2020 by SDP for explicit completeness + goto 300 + else + goto 365 + endif + else + goto 365 + endif + + write(6,240)1 + read(5,*)inn(1) + + do j = 1, inn(1) + write(6,250)1,j + read(5,*)znumb(1,j),anumb(1,j), elnum(1,j) + concn(1,j)=1. + enddo + + goto 300 + +c Find the thickness of the material required to stop the stopee. +600 write(6,610) + read(5,*)j + +615 tethk = 0.01 + if(den(j).eq.(2.329).AND.znumb(j,1).eq.14.AND. + + anumb(j,1).eq.28.AND.elnum(j,1).eq.1.and.isg(j).eq.0)then + error = siupb * 0.2329 + do while (1.eq.1) + zp = z + thk(j) = tethk + edep = 0.0 + call desorb(ianz, zp, a, energy, loste) + do k=1,ianz + edep = edep + loste(k) + enddo + if(edep.ge.energy.AND.error.lt.(0.01/0.2329))then + write(6,625) + write(6,620)tethk/0.2329+0.01 + exit + elseif(edep.ge.energy.AND.tethk.eq.0.01)then + write(6,625) + write(6,620)0.01 + write(6,*)edep + exit + elseif(edep.lt.energy.AND.tethk.ge.siupb*0.2329)then + write(6,630) + exit + elseif(edep.ge.energy)then + tethk = tethk - error + error = error/2.0 + elseif(edep.lt.energy)then + tethk = tethk + error + error = error/2.0 + endif + enddo + elseif(isg(j).eq.0)then + error = soupb + do while (1.eq.1) + zp = z + thk(j) = tethk + edep = 0.0 + call desorb(ianz, zp, a, energy, loste) + do k=1,ianz + edep = edep + loste(k) + enddo + if(edep.ge.energy.AND.error.lt.0.01)then + write(6,625) + write(6,621)tethk+0.01 + exit + elseif(edep.ge.energy.AND.tethk.eq.0.01)then + write(6,625) + write(6,621)0.01 + exit + elseif(edep.lt.energy.AND.tethk.ge.siupb)then + write(6,631) + exit + elseif(edep.ge.energy)then + tethk = tethk - error + error = error/2.0 + elseif(edep.lt.energy)then + tethk = tethk + error + error = error/2.0 + endif + enddo + elseif(isg(j).eq.1)then + error = gaupb + do while (1.eq.1) + zp = z + xln(j) = tethk + edep = 0.0 + call desorb(ianz, zp, a, energy, loste) + do k=1,ianz + edep = edep + loste(k) + enddo + if(edep.ge.energy.AND.error.lt.0.01)then + write(6,625) + write(6,622)tethk+0.01 + exit + elseif(edep.ge.energy.AND.tethk.eq.0.01)then + write(6,625) + write(6,622)0.01 + exit + elseif(edep.lt.energy.AND.tethk.ge.siupb)then + write(6,632) + exit + elseif(edep.ge.energy)then + tethk = tethk - error + error = error/2.0 + elseif(edep.lt.energy)then + tethk = tethk + error + error = error/2.0 + endif + enddo + else + write(6,630) + endif + + goto 10 + +610 format(/'Which layer would you like to vary to determine', + +/'how much of it is required to stop the stopee?') + +620 format(/f10.2, ' microns') +621 format(/f10.2, ' mg/cm2') +622 format(/f10.2, ' cm') +625 format(/'Amount of absorber to stop the stopee') + +630 format(/'Not even 232 microns of the absorber stop the stopee.') +631 format(/'Not even 1 g/cm2 of the absorber stop the stopee.') +632 format(/'Not even 1 m of the absorber stop the stopee.') + +633 format(/'The absorber is neither a gas nor a solid...') + + +c Perform caculation +400 zp = z + call desorb(ianz, zp, a, energy, loste) + + edep = 0.0 + + +c If particle stopped in a layer set the energy loss to zero in the rest + + do j = 1, ianz + edep = edep + loste(j) + if(edep.ge.energy)then + do k = j + 1, ianz + 1 + loste(k) = 0.0 + enddo + goto 402 + endif + enddo + +c Produce output +402 write(6,510)z,a, energy + write(7,510)z,a, energy + write(6,520)ianz + write(7,520)ianz + + do i = 1 ,ianz + if(isg(i).eq.0)then + write(6,530)i + write(7,530)i + write(6,540)den(i),thk(i) + write(7,540)den(i),thk(i) + elseif(isg(i).eq.1)then + write(6,550)i + write(7,550)i + write(6,560)prs(i),xln(i) + write(7,560)prs(i),xln(i) + endif + + do j = 1, inn(i) + write(6,570)znumb(i,j),anumb(i,j),elnum(i,j) + write(7,570)znumb(i,j),anumb(i,j),elnum(i,j) + enddo + + write(6,410)loste(i) + write(7,410)loste(i) + + enddo + + write(6,420)loste(ianz+1) + write(7,420)loste(ianz+1) + write(6,430) + + goto 10 + +410 format('Energy lost in layer = ',f7.3,' MeV') +420 format(/'Energy remaining = ',f7.3,' MeV') +430 format(/'Output also written to stopit.log') + +500 write(6,510)z,a, energy + write(6,520)ianz + + do i = 1 ,ianz + if(isg(i).eq.0)then + write(6,530)i + write(6,540)den(i),thk(i) + elseif(isg(i).eq.1)then + write(6,550)i + write(6,560)prs(i),xln(i) + endif + + do j = 1, inn(i) + write(6,570)znumb(i,j),anumb(i,j),elnum(i,j) + enddo + enddo + + goto 10 + +510 format(//'Charged particle has Z = ',f3.0,' A = ',f3.0,' Initial + +energy = ',f8.3,' MeV.') +520 format(//'Absorber contains ',I2,' layers.') +530 format(//'Layer # ',I2,' - Solid Absorber') +540 format('Density = ',e10.4,' g/cm3 Thickness = ',e10.4,' + +mg/cm2') +550 format(//'Layer # ',I2,' - Gas Absorber') +560 format('Pressure = ',e10.4,' Torr Length = ',e10.4,' cm') +570 format('Z = ',f3.0,' A = ',f3.0,4x,'Atoms per molecule = ',f3.0) + +1000 stop + end diff --git a/anasen_analysis_vignesh/eloss_calculations/stopit/stopit_pex.py b/anasen_analysis_vignesh/eloss_calculations/stopit/stopit_pex.py new file mode 100644 index 0000000..b26bf1c --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/stopit/stopit_pex.py @@ -0,0 +1,87 @@ +import pexpect as px +import sys,time,os +import matplotlib.pyplot as plt + +if len(sys.argv) != 8: + print("Usage: python3 stopit_pex.py ") + print("Modify the \#absorber section in script to change stopping material") + quit() + +stoppeeZ=int(sys.argv[1]) +stoppeeA=int(sys.argv[2]) +layer1_thickness = float(sys.argv[3]) #um +layer2_thickness = float(sys.argv[4]) #um +min_stoppee_energy=float(sys.argv[5]) +max_stoppee_energy=float(sys.argv[6]) +step_stoppee_energy=float(sys.argv[7]) + +#plotting prep +''' +plt.ion() +fig=plt.figure() +ax=fig.add_subplot(111) +ax.autoscale_view(True,True,True) +line,=ax.plot([],[],'b-') +ax.set_xlim(0,0.5*max_stoppee_energy) +ax.set_ylim(0,0.05*max_stoppee_energy) +''' +stopit_child = px.spawn("./a.out") +stopit_child.logfile = None + +def run_stopit(child,Z,A,Energy_MeV,thickness_um): + child.expect("7 stop\r") + + #stoppee + child.send("1\r") + child.expect("Enter Z and A of stopee.\r") + child.send(str(Z)+" "+str(A)+"\r") + child.expect("Enter energy in MeV.\r") + child.send(str(Energy_MeV)+"\r") + + #absorber - standard medium, Si + child.expect("7 stop\r") + child.send("2\r") + child.expect("\r") + child.send("1\r") + child.expect("He, and H2\)\r") + child.send("2\r") + child.expect("H2-gas\r") + child.send("2\r") #first 2 for 'define absorber', then 1 for '1 layer', then 2 for 'standardized material', then '2' for Si. + child.expect("\r") + child.send(str(thickness_um)+"\r") + + #run! + child.expect("7 stop\r") + child.send("4\r") + child.expect("stopit.log\r") + #get all the output that shows up before the string 'stopit.log' above. + #the split() splits it up at all whitespaces. we can pick out the substrings of interest from this bunch now + results = child.before.decode('utf-8').split() + + return [results[12],results[48],results[53]] + +layer1_edep = [] +layer2_edep = [] +stoppee_energy = min_stoppee_energy #in MeV +while(stoppee_energy < max_stoppee_energy): + [in_en,e_lost ,e_left ] = run_stopit(stopit_child,stoppeeZ,stoppeeA,stoppee_energy,layer1_thickness) + [in_en,e_lost2,e_left2] = run_stopit(stopit_child,stoppeeZ,stoppeeA,e_left ,layer2_thickness) + + print(stoppee_energy,e_lost,e_lost2) + sys.stdout.flush() + layer1_edep.append(float(e_lost)) + layer2_edep.append(float(e_lost2)) + ''' + line.set_data(layer2_edep,layer1_edep) #dE in y-axis, E in x-axis when possible + ax.relim() + plt.draw() + plt.pause(0.004) + ''' + stoppee_energy += step_stoppee_energy + +stopit_child.expect("7 stop\r") +stopit_child.send("7\r") +stopit_child.expect(px.EOF) +stopit_child.close() + +plt.show(block=True) diff --git a/anasen_analysis_vignesh/eloss_calculations/test_tgraph.C b/anasen_analysis_vignesh/eloss_calculations/test_tgraph.C new file mode 100644 index 0000000..e385a89 --- /dev/null +++ b/anasen_analysis_vignesh/eloss_calculations/test_tgraph.C @@ -0,0 +1,17 @@ +void test_tgraph() { + TGraph MeV_to_cm("alphas_in_250torr_mix_filtered.txt","%lf %*lf %lf"); + TGraph cm_to_MeV(MeV_to_cm.GetN(), MeV_to_cm.GetY(), MeV_to_cm.GetX()); + + MeV_to_cm.Draw("AL"); + while(gPad->WaitPrimitive()); + cm_to_MeV.Draw("AL"); + gPad->Modified(); gPad->Update(); + while(gPad->WaitPrimitive()); + + double e=6.0,L=4.0; + while(e>5.0) { + double temp = MeV_to_cm.Eval(e)-L; + std::cout << "If we detect an alpha at " << e << " MeV, covering a path of " << L << " cm, " << cm_to_MeV.Eval(MeV_to_cm.Eval(e)-L) << " MeV is its original energy " << L << " cm prior" << std::endl; + e-=0.05; + } +} diff --git a/anasen_analysis_vignesh/feeder.py b/anasen_analysis_vignesh/feeder.py new file mode 100644 index 0000000..768b567 --- /dev/null +++ b/anasen_analysis_vignesh/feeder.py @@ -0,0 +1,24 @@ +import keyboard +import time +fi = open("/tmp/eventlist.dat","r") +lines = fi.readlines()[3:] +fo = open("/tmp/coords","w") +for line in lines: + if("--" not in line): + print(line,end='') + fo.write(line) + fo.flush() + else: + if("end" in line): + while True: + time.sleep(2) + key = "n" + #key = input() + if 'n' in key: + break + fo.seek(0) + fo.truncate(0) + print(line,end='') + +fo.close() +fi.close() diff --git a/anasen_analysis_vignesh/gmsx3/func1.h b/anasen_analysis_vignesh/gmsx3/func1.h new file mode 100644 index 0000000..620b787 --- /dev/null +++ b/anasen_analysis_vignesh/gmsx3/func1.h @@ -0,0 +1,41 @@ +#include "TF1.h" + +double model2(double *x, double *par) { + /* 'Potential Well' of width 2a from from xx-a to xx+a + xx is coordinate about the point of origin, set at x=center + v0 is the y-offset of the potential + k is the 'steepness' of the potential + + continuous across xx-a and xx+a, and differentiable + */ + + double center= par[3]; + double xx = x[0]-center; + double a = TMath::Abs(par[0]); + double k = TMath::Abs(par[1]); + double v0 = par[2]; + + if(xx < -a) + return k*(xx+a)*(xx+a) + v0; + else if(xx > a) + return k*(xx-a)*(xx-a) + v0; + else + return v0; +} + +void func1() { + //TF1 f1("bowl",model,-2.,2.,2); + TCanvas c("c1","c1",800,600); + TF1 f1("bowl",model2,-10.,10.,4); + f1.SetMaximum(10); + + for(int i=-4; i<4; i++) { + f1.SetParameters(.4,100,2,i); //a, k, v0, center + f1.SetNpx(100000); + if(i==-4) f1.Draw("L"); + f1.DrawCopy("L SAME"); + c.Modified(); c.Update(); + //c.SaveAs(Form("%d.png",out)); + while(c.WaitPrimitive()); + } +} diff --git a/anasen_analysis_vignesh/gmsx3/intgm_sx3.h b/anasen_analysis_vignesh/gmsx3/intgm_sx3.h new file mode 100644 index 0000000..837c292 --- /dev/null +++ b/anasen_analysis_vignesh/gmsx3/intgm_sx3.h @@ -0,0 +1,216 @@ +#include "../Armory/HistPlotter.h" +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "func1.h" +static long iters=0; + +//class intgm_sx3 : public ROOT::Minuit2::FCNBase { +class intgm_sx3 { + int N; + + //L.at(0).at(3).at(n) is front strip = 0, back pad = 3, nth datapoint + std::array,4>,4> L,R,B; + //std::array,4> stripedge; //stripedge.at(i).at(j) is the jth edge of the ith strip. there are five edges for the four strips 'i'=0 to 3, (0,1) (1,2) (2,3) (3,4) for each + //the edges are at -2a, -a, 0, a, 2a respectively so we enforce four ratios in the chi2 value - 'a' can be held constant, no need to fit it. + + //assume z = M*(aL-bR) + //stripedge[i][1] = max(z) when pad==0 = min(z) when pad==1 this should be -1 + //stripedge[i][2] = max(z) when pad==1 = min(z) when pad==2. this should be 0 + //stripedge[i][3] = max(z) when pad==2 = min(z) when pad==3. this should be 1 + + //i.e. stripedge[i][j] = max(z) when pad == j-1, min(z) when pad==j, for i= 1,2,3 + + //ncounts.at(frontch).at(backch) is the number of (L,R,B) tuples we've filled (frontch,backch) coordinates in the detector + std::array,4> ncounts; + TH1F *localhists[4][4]; //one histogram for each fc, bc combination + HistPlotter *plotter; + TF1 *pos_weight[4]; + TF1 *energywell; + public: + intgm_sx3() { + for(int bc=0; bc<4; bc++) { + for(int fc=0; fc<4; fc++) { + L[fc][bc].reserve(1000); + R[fc][bc].reserve(1000); + B[fc][bc].reserve(1000); + //localhists[fc][bc] = new TH1F(Form("h_%d_%d",fc,bc),Form("h_%d_%d",fc,bc),1000,-4.,4.); + ncounts[fc][bc] = 0; + } + pos_weight[bc] = new TF1(Form("b_strip%d",bc),model2,-10,10,4); //from -10, to 10, 4 parameters + pos_weight[bc]->SetParameters(1.0,10,1.,3-2*bc); //centers at 1, 3.,5,7 Width 2a with a=1.0 + pos_weight[bc]->SetNpx(1'000'000); + } + energywell = new TF1("ewell",model2,0,2000,4); //0 to 2000 channels, 4 params + energywell->SetParameters(1000,20,1,1500); //center the back E values at 1500 +/- 500 + energywell->SetNpx(1'000'000); + N=0; + } + void set_plotter(HistPlotter *p) {plotter=p;} + void set_iters(long i) { iters=i;} + intgm_sx3(HistPlotter *p) : plotter(p) { + for(int bc=0; bc<4; bc++) { + for(int fc=0; fc<4; fc++) { + L[fc][bc].reserve(1000); + R[fc][bc].reserve(1000); + B[fc][bc].reserve(1000); + //localhists[fc][bc] = new TH1F(Form("h_%d_%d",fc,bc),Form("h_%d_%d",fc,bc),1000,-4.,4.); + ncounts[fc][bc] = 0; + } + pos_weight[bc] = new TF1(Form("b_strip%d",bc),model2,-10,10,4); //from -10, to 10, 4 parameters + //a/2, k, v0, center + pos_weight[bc]->SetParameters(0.92,10,1.,-1.*(3-2*bc)); //centers at 7, 5.,3,1 Width 2a with a=1.0 + pos_weight[bc]->SetNpx(1'000'000); + } + energywell = new TF1("ewell",model2,0,8000,4); //0 to 2000 channels, 4 params +// energywell->SetParameters(60,10,0,1430); //center the back E values at 1430 +/- 60 + energywell->SetParameters(400,10,0,5246); //center the back E values at 5486 +/- 600 + energywell->SetNpx(1'000'000); + N=0; + } + + inline void fill(int fc, int bc, double leftE, double rightE, double backE) { + /* + * + */ + assert(fc>=0 && fc<=3 && "Front channels should fit the range 0 to 3 inclusive!"); + assert(bc>=0 && bc<=3 && "Back channels should fit the range 0 to 3 inclusive!"); + if(leftE>0 && rightE >0 && backE>0) { + L[fc][bc].emplace_back(leftE); + R[fc][bc].emplace_back(rightE); + B[fc][bc].emplace_back(backE); + ncounts[fc][bc]+=1; + N+=1; + } + } + + inline void print() { + for(int i=0; i<16; i++) { + std::cout << ncounts[i%4][i/4] << std::endl; + } + } + inline void plot(std::string comment, const double* params) { + std::array l,r,b,bo,ro,lo,offset,stretch; //aliases to help with book-keeping + std::array,4> back_gains;// back_gains[fc][bc] are for fc,bc firing in combo + for(int ctr=0; ctr<4; ctr++) { + r[ctr] = params[ctr]; + } + for(int ctr=4; ctr<20; ctr++) { + int bch = (ctr-4)%4; + int fch = (ctr-4)/4; + back_gains[bch][fch] = params[ctr]; + } + for(int ctr=20; ctr<24; ctr++) { + stretch[ctr-20] = params[ctr]; + } + for(int ctr=24; ctr<28; ctr++) { + l[ctr-24] = params[ctr]; + } + for(int fc=0; fc<4; fc++) { + for(int bc=0; bc<4; bc++) { + for(int n=0; nFill2D(Form("normlf_fc%d_%d_%s",fc,bc,comment.c_str()),800,0,1.,800,0,1.,left/back, right/back,"l_vs_r"); + plotter->Fill2D(Form("normlf_all_%s",comment.c_str()),800, 0, 1., 800, 0, 1.,left/back, right/back); + plotter->Fill2D(Form("case_f%d_b%d_%s",fc,bc,comment.c_str()),800,0,8192,800,0,8192,left+right,back,"l_vs_r"); + plotter->Fill2D(Form("case_all_%s",comment.c_str()),800,0,8192,800,0,8192,left+right,back); + //plotter->Fill2D(Form("z_vs_backe_f%d_b%d_%s",fc,bc,comment.c_str()),800,-10,10,800,0,8192,zpos,back,"z_vs_be"); + plotter->Fill2D(Form("z_vs_backe_all_%s",comment.c_str()),800,-10,10,800,0,8192,zpos,back); + } //end if plotter + }// end for-n + }//end for-bc + }//end for-fc + }//end plot() + + // double operator()(const std::vector& params) const override{ + double eval(const double* params) const { + iters+=1; + + std::array l,r,b,bo,ro,lo, offset, stretch; //aliases to help with book-keeping + std::array,4> back_gains;// back_gains[fc][bc] are for fc,bc firing in combo + for(int ctr=0; ctr<16; ctr++) { + int bch = (ctr)%4; + int fch = (ctr)/4; + back_gains[bch][fch] = params[ctr]; + } + for(int ctr=16; ctr<20; ctr++) { + r[ctr-16] = params[ctr]; + l[ctr-16] = 1.0; + } + for(int ctr=20; ctr<24; ctr++) { + stretch[ctr-20] = params[ctr]; + } + double result=0, sumcount=0; + for(int fc=0; fc<4; fc++) { + for(int bc=0; bc<4; bc++) { + //if(bc >= 1 || fc >= 1 ) continue; + if(ncounts[fc][bc] == 0 && iters ==0) { + std::cout << "Missing any data in front:" << fc << " back:" << bc << " combination." << std::endl; + } + + for(int n=0; nEval(zpos) << " " << bc << std::endl; + double add_position = pos_weight[bc]->Eval(zpos); + double eback_align_penalty = energywell->Eval(back); +/* if(back>1000) zmid[fc][bc] += zpos; + if(back>1000 && zpos < zmin[fc][bc]) zmin[fc][bc] = zpos; + if(back> 1000 && zpos > zmax[fc][bc]) zmax[fc][bc] = zpos; + + if(back>1000) { + localhists[fc][bc]->Fill(zpos); + }*/ + + result += add_position; + //result += add; + result += eback_align_penalty; + sumcount+=1; + //if(bc==0) std::cout << add << " " << add_position << " " << zpos << std::endl; + //To avoid drift towards (0,0,0) trivial solution. This value ~1 close to (1,1,1) + //result+=(1e-3/(TMath::Power(l[fc],2)+TMath::Power(r[fc],2)+TMath::Power(b[bc],2)+1e-9)); + //result+=(1e-3/(TMath::Power(l[fc],2)+TMath::Power(r[fc],2)+TMath::Power(b[bc],2)+1e-9)); + } //end for-n + } //end for-bc + } //end for-fc + result/=sumcount; //normalize, so the value doesn't scream + if(iters%1'000==0) { + std::cout << "iters : " << iters << " params: " << std::endl ; + for(int i=0 ; i< 10; i++) std::cout << params[i] << " " << std::flush; + std::cout<< std::endl; + for(int i=10 ; i< 20; i++) std::cout << params[i] << " " << std::flush; + std::cout << std::endl << " result: " << result << std::endl; + } //end if + return result; + } //end eval() + + //double Up() const override { return 1.0; } // Required by minuit2 FCBase + +}; + diff --git a/anasen_analysis_vignesh/gmsx3/utilities_orr.h b/anasen_analysis_vignesh/gmsx3/utilities_orr.h new file mode 100644 index 0000000..2c6566a --- /dev/null +++ b/anasen_analysis_vignesh/gmsx3/utilities_orr.h @@ -0,0 +1,338 @@ +#ifndef UTILS_ORR_H +#define UTILS_ORR_H +#include "datatypes.h" +#include "HistPlotter.h" +#include "Geometry_orr.h" //contains orruba geometry constants +#include +#include +#include +#include +#include +#include +#include +//#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "TMath.h" +#include "counters.h" + +static named_counter oc("named orruba counters"); + +inline float get_filesize(std::string filename) { + struct stat st; + stat(filename.c_str(), &st); + return st.st_size; +} + +class orruba_params { + /* + * + */ +public: + int chnum=DEFAULT_NULL; //!< global channel number + std::string type = "-"; + int id=DEFAULT_NULL; + int layer=DEFAULT_NULL; + int frontback=DEFAULT_NULL; + int updown=DEFAULT_NULL; + int subid=DEFAULT_NULL; + int leftright=DEFAULT_NULL; + + float ped=DEFAULT_NULL; + float offset=DEFAULT_NULL; + float gain=DEFAULT_NULL; + float gain2=DEFAULT_NULL; //for use with sx3's +}; + +class sx3_geometry_scalefactors { +public: + //If sx3 has L, R being the left and right extremities, we choose add, stretch here such that + // x_mm = (x_raw+add)*stretch; so add=abs(L), stretch=75/(abs(L)+R) + float add[4]; + float stretch[4]; +}; + +class qqq5_finegains { +public: + std::array,32> front; + //front.at(30).first = slope at clkpos 0, ring 30 for E front layer + //front.at(30).second = intercept for the same as above + std::array,4> back; +}; +class sx3_fbgains { +public: + //Order of indices is [pad][strip] + float padoffsets[4][4]; + float padgains[4][4]; + + float stripLoffsets[4][4]; + float stripLgains[4][4]; + + float stripRoffsets[4][4]; + float stripRgains[4][4]; +}; + +//Metadata ORRUBA needs to know about itself, to be configured at the start +extern std::array o_params; +extern std::array sx3_xtalk_gains; //every sx3 needs to be gainmatched as a frontL-back, frontR-back pair (pad strip pair) +extern std::array sx3gs; +extern std::array qqq5_fg_dE, qqq5_fg_E; + +class type19Raw { +public: + long int timestamp; + std::vector ch; + std::vector val; + + type19Raw() : timestamp(0), ch(50,0), val(50,0) {} //Reserve 50 for size of these vectors, initial value of zero + void print() const { + /* + print() + Prints type19Raw's contents to stdout for monitoring + */ + std::cout << "------" << std::endl; + for(unsigned int ii=0; ii back[4]; + std::vector frontL[4]; + std::vector frontR[4]; + + double ts = DEFAULT_NULL; + //Easy lookup of final calibrated event. Only filled for valid cases, assumed for now to be 1L, 1R, 1B + float frontX=DEFAULT_NULL; + float frontXmm=DEFAULT_NULL; + float frontE=DEFAULT_NULL; + float backE=DEFAULT_NULL; + int stripF=DEFAULT_NULL; + int stripB=DEFAULT_NULL; + float frontEL=DEFAULT_NULL; + float frontER=DEFAULT_NULL; + + float phi=DEFAULT_NULL; // + + std::set valid_front_chans; + std::set valid_back_chans; + std::set unmatched_front_chans; //every front channel is unmatched and invalid at first. when it gets matched, it gets removed and sent to valid + + bool foundevent=false; + bool valid=false;//valid will be set to false in all cases where we have ambiguity + int flags=-1;//flags settable to different types of values to indicate different invalid situations + + void fillevent(const std::string& position, const int subchannel, const float value); //make 'const' what functions don't need to change, helps with performance + void validate(const sx3_fbgains&, const sx3_geometry_scalefactors&); +}; + +class qqq5 { +public: + //Holds all information in an event, including ped subtraction+scaling. front[2].at(0) will have the largest energy seen in ch2, if any + //TODO: Convert to std::array + std::vector back[4]; + std::vector front[32]; + + double ts = DEFAULT_NULL; + float selftheta=DEFAULT_NULL,selfrho=DEFAULT_NULL; + //Easy lookup of the final calibrated event. Only filled for valid cases. + double frontE=DEFAULT_NULL; + double backE=DEFAULT_NULL; + int frontch; + int backch; + + std::pair adj_front_strips = {-1,-1}; + std::pair adj_back_strips = {-1,-1}; + std::set valid_front_chans; //list of channels that fire. can inspect size() of these to see if there are front/back events + std::set valid_back_chans; // we use std::set since it makes for very readable code + + bool foundevent=false; + bool valid=false; //valid will be set to false in all cases where we have ambiguity + int flags=-1; //flags settable to different types of values to indicate different invalid situations + + void fillevent(const std::string& position, const int subchannel, const float value); //make 'const' what functions don't need to change, helps with performance + void validate(); +}; + +struct orrubaevent { + //Every clean, valid charged-particle event will have these four parts + float dE=DEFAULT_NULL; //!< true energy-loss in the dE layer. Found by gainmatching ADC readout to alpha data + float E=DEFAULT_NULL; //!< energy deposited in the E layer. When summed with dE, gives true energy in keV deposited by the particle in ORRUBA + float dE_PID = DEFAULT_NULL; //!< dE scaled for dE-layer's thickness, reducing the spread due to angular straggling by explicitly accounting for it. This will give a sharper pid plot that can be gated on better + float dE_linPID = DEFAULT_NULL; //!< dE_PID, but linearized using the prescription described in, say, PhysRevC.90.034601 (2014). dE_linPID = ((dE+E)^a-E^a)^(1/a) where a ~ 1.68 is chosen empirically + float Theta=DEFAULT_NULL; //!< Laboratory polar angle of event in radians, deprecated + float Phi=DEFAULT_NULL; //!< Lab azimuthal angle of event in radians, deprecated + + //Helpful indices to make dE-E plots + std::string type; //!< "endcap" vs "barrel" + //!< Identify the position of the detector in the barrel, usually in accordance with the channel map: say we might learn detector is at "Quad 4" or "clk_pos 10", together with 'type'. Useful with HistPlotter class + int position=DEFAULT_NULL; + int subchdE_1=DEFAULT_NULL, subchdE_2=DEFAULT_NULL; //!< Identify the subchannels corresponding to the two sides of the dE detector. To avoid confusion, 1=strip(sx3), ring(qqq) and 2=pad(sx3), wedge(qqq) + int subchE_1=DEFAULT_NULL, subchE_2=DEFAULT_NULL; //!< Identify the subchannels corresponding to the two sides of the E detector. Same convention as above + + float x=DEFAULT_NULL,y=DEFAULT_NULL,z=DEFAULT_NULL; //!< Laboratory x,y,z coordinates of the event from the E layer + float r0=DEFAULT_NULL,theta0=DEFAULT_NULL,phi0=DEFAULT_NULL; //!< vector elements from hit to origin for E layer + float r1=DEFAULT_NULL,theta1=DEFAULT_NULL,phi1=DEFAULT_NULL; //!< vector elements from hit to origin for dE layer +}; + +/*TODO: + * There will be some use for a class such that it stores + PhysicsEvent = + * Once the 'orrubaevent' structs are made, it should be callable. like + std::vector getPhysicsFromVertices(Kinematics dpkin, std::vector orvec);? + * should the physics just go sit in orrubaevent? maybe orruba2024 class can have a kinematics object in it? +*/ + +class orruba2024 { +private: +//Class expected to be changed for each version of the analysis code +public: + bool found_trk, found_trkpresc, found_tdcq, found_s800e1, found_s800trg, + found_rf, found_gt, found_si, found_siup; + + bool found_de, found_e, found_qqq, found_sx3;//orruba + long long timestamp=DEFAULT_NULL; + std::vector o_rawvec; + + std::array uendcapE; + std::array uendcapdE; + std::array ubarrelE; + std::array ubarreldE; + + std::array dbarrelE; + //Results after post-processing, including possible multiplicities + std::vector events; + + double target_z_offset; + + //void initialize(const std::string & filename1, const std::string& filename2, const std::string& filename3); + float tdc_trk = DEFAULT_NULL; + float tdc_trksi = DEFAULT_NULL; //trackerpr+si stops are combined into one channel + float tdc_trkp = DEFAULT_NULL; + float tdc_q = DEFAULT_NULL; + float tdc_s800e1 = DEFAULT_NULL; + float tdc_s800trg = DEFAULT_NULL; + float tdc_rf = DEFAULT_NULL; + float tdc_rf_unwrap = DEFAULT_NULL; + float tdc_gt = DEFAULT_NULL; + float tdc_si = DEFAULT_NULL; + float tdc_siup = DEFAULT_NULL; + orruba2024(const std::vector& orvec); + void postprocess(); //generates 'events', and performs validations on freshly entered data. performs fine gainmatching for front-back-pairs + void print() const { + std::cout << Form("TDCs\n trk:%1.4f\ntrkp:%1.4f\nq:%1.4f\ns800e1:%1.4f\ns800trg:%1.4f\nrf:%1.4f\nrfuw:%1.4f\ngt:%1.4f\nsi:%1.4f\nsiup:%1.4f\n-----\nevents_size:%lu\ntimestamp:%lld\nfound_de:%d, found_e:%d\n-------\n-------\n", + tdc_trk, tdc_trkp, tdc_q, tdc_s800e1, tdc_s800trg, tdc_rf, tdc_rf_unwrap, tdc_gt, tdc_si, tdc_siup, events.size(), timestamp, found_de, found_e) << std::endl; + } +}; + +class trackingdet { +public: + double timestamp=DEFAULT_NULL; + //TODO: Convert all to std::array + std::vector xwires[MAXNWIRES_TRACK]; + std::vector ywires[MAXNWIRES_TRACK]; + std::vector xwiresf[MAXNWIRES_TRACK]; + std::vector ywiresf[MAXNWIRES_TRACK]; + std::vector xwiresf_nn[MAXNWIRES_TRACK]; + std::vector ywiresf_nn[MAXNWIRES_TRACK]; + + std::vector xtimes[MAXNWIRES_TRACK]; + std::vector ytimes[MAXNWIRES_TRACK]; + std::vector xtimesf[MAXNWIRES_TRACK]; + std::vector ytimesf[MAXNWIRES_TRACK]; + std::vector cathode; + + int multx; //how many x-wires fired? + int multy; //how many y-wires fired? + int multxf; //how many filtered x-wires fired? + int multyf; //how many filtered y-wires fired? + + int multxt; //how many x-tdcwires fired? + int multyt; //how many y-tdcwires fired? + + int multxtf; //how many x-tdcwires fired in window? + int multytf; //how many y-tdcwires fired in window? + + float tot_cathode=0; + float tot_x=0; + float tot_y=0; + float tot_anode=0; + + //list of x and y wires fired above energy threshold, within timing gate window + std::set list_ywires; + std::set list_xwires; + + std::set list_ytwires; + std::set list_xtwires; + + //position of the vertex estimated by up to 2 neighbouring wires firing together within window + double xpos=DEFAULT_NULL; + double ypos=DEFAULT_NULL; + bool clean_event = false; + int maxnx=-124, maxny=-124; + int nnx = 0; //nearest neighbour x wires set this to +/- 1 if present w.r.t. wire maxnx + int nny = 0; //nearest neighbour y wires set this to +/- 1 if present w.r.t wire maxny + bool clean_event_no_timing = false; + bool clean_single_xy_event = false; + bool clean_single_xy_event_no_timing = false; + void Reset() { + /*** + Resets all data members. + **/ + cathode.clear(); + for(int i=0; i& orvec); +}; + +const float alpha = 0.0; +int matchchantype(unsigned short chan, const std::array& index, const std::string& label); +void initialize_orruba(const std::string & filename1, const std::string& filename2, const std::string& filename3, const std::string& filename4);//, +int parse_orruba_data(const unsigned short* buffer, int32_t length, type19Raw& oraw_event); +#endif diff --git a/anasen_analysis_vignesh/gnuplot_lookerup b/anasen_analysis_vignesh/gnuplot_lookerup new file mode 100644 index 0000000..9192dcc --- /dev/null +++ b/anasen_analysis_vignesh/gnuplot_lookerup @@ -0,0 +1,80 @@ + +# --- configuration --- +datafilec = "../ANASEN_analysis/PW_study_Sudarsan/cathode1_2.dat" +datafilea = "../ANASEN_analysis/PW_study_Sudarsan/anode1_2.dat" +datafileqr = "../ANASEN_analysis/PW_study_Sudarsan/qqq_rings_geometry.dat" +datafileqw = "../ANASEN_analysis/PW_study_Sudarsan/qqq_wedges_geometry.dat" + +set datafile separator "," + +N = 24 #number of cids + +# --- allocate arrays --- +array ca1x[N] +array an1x[N] +array ca1y[N] +array an1y[N] +array ca1z[N] +array an1z[N] +array ca2x[N] +array an2x[N] +array ca2y[N] +array an2y[N] +array ca2z[N] +array an2z[N] +array qqqW_Phi[64] +array qqqR_Rho[16] + +# --- initialize (optional but safe) --- +do for [i=1:N] { + ca1x[i] = ca1y[i] = ca1z[i] = NaN; + ca2x[i] = ca2y[i] = ca2z[i] = NaN; + an1x[i] = an1y[i] = an1z[i] = NaN; + an2x[i] = an2y[i] = an2z[i] = NaN; +} + +do for [j=1:16] { + do for [i=1:4] { + qqqW_Phi[i*4+j] = NaN + } + qqqR_Rho[j] = NaN +} + + +# --- load table into arrays --- +stats datafilec using \ + (ca1x[int($1)+1] = $2, \ + ca1y[int($1)+1] = $3, \ + ca1z[int($1)+1] = $4, \ + ca2x[int($1)+1] = $5, \ + ca2y[int($1)+1] = $6, \ + ca2z[int($1)+1] = $7, 0) \ + nooutput + +stats datafilea using \ + (an1x[int($1)+1] = $2, \ + an1y[int($1)+1] = $3, \ + an1z[int($1)+1] = $4, \ + an2x[int($1)+1] = $5, \ + an2y[int($1)+1] = $6, \ + an2z[int($1)+1] = $7, 0) \ + nooutput + +set datafile separator "\t" +stats datafileqr using \ + (qqqR_Rho[int($1)+1] = $2, 0) \ + nooutput + +stats datafileqw using \ + (qqqW_Phi[(int($1))*4+int($2)+1] = $3, 0) \ + nooutput + +#do for [i=1:N] { +# print sprintf("Data[%d] = %g", i, an1x[i]) +# print sprintf("Data[%d] = %g", i, ca1x[i]) +#} + +set datafile separator whitespace +#plot '< cat /tmp/coords | grep q' u (ca1x[int($2)+1]):(ca1y[int($2)+1]):(ca1x[int($2)+1]):(ca1y[int($2)+1]) w vector + +#pause mouse key diff --git a/anasen_analysis_vignesh/live_plotter b/anasen_analysis_vignesh/live_plotter new file mode 100644 index 0000000..60fa783 --- /dev/null +++ b/anasen_analysis_vignesh/live_plotter @@ -0,0 +1,41 @@ +#columns: +#1 is anodeindex, 2 is cathodeindex, 3,4,5 is crossover x,y,z, 6 is alpha - 7,8,9 are anode loci (first plane), 10, 11, 12 are cathode loci (first plane). +#13,14,15 are anode second plane loci, 16,17,18 are cathode second plane loci + +#set term qt font 'Verdana,10' size 1920,1080 +set term x11 font 'terminus-16' size 1920,1080 noraise +#set key outside +pause_status=0 +load 'gnuplot_lookerup' +bind all "x" "pause_status=!pause_status" +set datafile separator "," + +#anode-cathode-raw-loci, junction points colored same as anode wires +set title sprintf('press ctrl+q to redraw, Ctrl+C the terminal to exit. pause\_status=%d',pause_status) +set xlabel 'x-axis' +set ylabel 'y-axis' +#set view 212,110,1,1 + +set xrange [-100:100] +set yrange [-100:100] +set zrange [-200:200] + +set zlabel 'z-axis' +splot '../ANASEN_analysis/PW_study_Sudarsan/results_zsort.dat' u 7:8:9:($13-$7):($14-$8):($15-$9):1 with vectors nohead dt 1 lc variable title 'anodes',\ + '' u 10:11:12:($16-$10):($17-$11):($18-$12):2 w vectors nohead dt 7 lc variable title 'cathodes',\ + '../ANASEN_analysis/PW_study_Sudarsan/results_zsort.dat' u 3:4:5:1 w lp ls 7 lc variable title 'vertices colored anode',\ + '< cat /tmp/coords | grep an' u (an1x[int($2)+1]):(an1y[int($2)+1]):(an1z[int($2)+1]):(an2x[int($2)+1]-an1x[int($2)+1]):(an2y[int($2)+1]-an1y[int($2)+1]):(an2z[int($2)+1]-an1z[int($2)+1]) w vector nohead lc 'black' lw 8 title 'selected\_anode',\ + '< cat /tmp/coords | grep ca' u (ca1x[int($2)+1]):(ca1y[int($2)+1]):(ca1z[int($2)+1]):(ca2x[int($2)+1]-ca1x[int($2)+1]):(ca2y[int($2)+1]-ca1y[int($2)+1]):(ca2z[int($2)+1]-ca1z[int($2)+1]) w vectors nohead lc 'grey' dt 2 lw 8 title 'selected\_cath',\ + '< cat /tmp/coords | grep q' u (qqqR_Rho[int($3)+1]*cos((pi/180.)*qqqW_Phi[int($2)*4+int($5)+1])):(qqqR_Rho[int($3)+1]*sin((pi/180.)*qqqW_Phi[int($2)*4+int($5)+1])):(128) w p ps 4 lc 'black' title 'qqqvertex' + #'' u 7:8:9:($1):1 w labels font ',10' tc variable notitle,\ + #'' u 13:14:15:($1):1 w labels font ',10' tc variable notitle,\ + #'' u 10:11:12:($2):2 w labels font ',10' tc variable notitle,\ + #'' u 16:17:18:($2):2 w labels font ',10' tc variable notitle +if(pause_status==0) { + pause 1.0 +} else { + reread + pause mouse close + pause_status=!pause_status +} +reread diff --git a/anasen_analysis_vignesh/mapping.h b/anasen_analysis_vignesh/mapping.h new file mode 100644 index 0000000..f5cc3da --- /dev/null +++ b/anasen_analysis_vignesh/mapping.h @@ -0,0 +1,334 @@ +#ifndef Mapping_h +#define Mapping_h + +#include +#include +#include +#include +#include +#include +#include + +#include + +const std::map board = { + {0, 17122}, // id, sn + {1, 17123}, + {2, 22320}, + {3, 22130}, + {4, 22129}, + {5, 15529}, + {6, 15528}, + // {7,89}, + {7, 334}, + {8, 379}, + {9, 325}, + {10, 405}}; +const int nBd = board.size(); + +const int nV1740 = 7; +const int nV1725 = 4; + +//+++++++++++++++++++ detID; +// The detectors are seperated into 2 type: SuperX3, QQQ, and PC +// the SuperX3 has 24 detectors for each kind, wach detector has 12 channels +// the QQQ has 4 detectors for each kind, each detector has 32 channels +// the PC has 2 types, anode and cathode, each has 24 channels +// the MISC has 6 channels, the lollipop IC and siliscon followed by the hotneedle IC, as well as the Rf and MCP +// The detID = Type * 10000 + index * 100 + channel +// fro example, detID(superX3-8, ch-7) = 00807 + +// use the GenMapping() to get that +const std::vector mapping = { + + //================== 17122 + 806, 807, 804, 805, 803, 802, 801, 800, 1006, 1007, 1004, 1005, 1003, 1002, 1001, 1000, + 606, 607, 604, 605, 603, 602, 601, 600, 1106, 1107, 1104, 1105, 1103, 1102, 1101, 1100, + 711, 710, 709, 708, 911, 910, 909, 908, 1011, 1010, 1009, 1008, 811, 810, 809, 808, + 706, 707, 704, 705, 703, 702, 701, 700, 906, 907, 904, 905, 903, 902, 901, 900, + //================== 17123 + 1406, 1407, 1404, 1405, 1403, 1402, 1401, 1400, 1606, 1607, 1604, 1605, 1603, 1602, 1601, 1600, + 1306, 1307, 1304, 1305, 1303, 1302, 1301, 1300, 1506, 1507, 1504, 1505, 1503, 1502, 1501, 1500, + 1311, 1310, 1309, 1308, 1711, 1710, 1709, 1708, 1611, 1610, 1609, 1608, 1411, 1410, 1409, 1408, + 1206, 1207, 1204, 1205, 1203, 1202, 1201, 1200, 1706, 1707, 1704, 1705, 1703, 1702, 1701, 1700, + //================== 22320 + 6, 7, 4, 5, 3, 2, 1, 0, 506, 507, 504, 505, 503, 502, 501, 500, + 111, 110, 109, 108, 311, 310, 309, 308, 411, 410, 409, 408, 211, 210, 209, 208, + 206, 207, 204, 205, 203, 202, 201, 200, 406, 407, 404, 405, 403, 402, 401, 400, + 106, 107, 104, 105, 103, 102, 101, 100, 306, 307, 304, 305, 303, 302, 301, 300, + //================== 22130 + 1911, 1910, 1909, 1908, 2111, 2110, 2109, 2108, 2211, 2210, 2209, 2208, 2011, 2010, 2009, 2008, + 11, 10, 9, 8, 511, 510, 509, 508, 611, 610, 609, 608, 1111, 1110, 1109, 1108, + 2006, 2007, 2004, 2005, 2003, 2002, 2001, 2000, 2206, 2207, 2204, 2205, 2203, 2202, 2201, 2200, + 1906, 1907, 1904, 1905, 1903, 1902, 1901, 1900, 2106, 2107, 2104, 2105, 2103, 2102, 2101, 2100, + //================== 22129 + 1806, 1807, 1804, 1805, 1803, 1802, 1801, 1800, 2306, 2307, 2304, 2305, 2303, 2302, 2301, 2300, + 10031, 10030, 10029, 10028, 10027, 10026, 10025, 10024, 10023, 10022, 10021, 10020, 10019, 10018, 10017, 10016, + // 10016, 10017, 10018, 10019, 10020, 10021, 10022, 10023, 10024, 10025, 10026, 10027, 10028, 10029, 10030, 10031, + 10116, 10117, 10118, 10119, 10120, 10121, 10122, 10123, 10124, 10125, 10126, 10127, 10128, 10129, 10130, 10131, + 10015, 10014, 10013, 10012, 10011, 10010, 10009, 10008, 10007, 10006, 10005, 10004, 10003, 10002, 10001, 10000, + //================== 15529 + 10231, 10230, 10229, 10228, 10227, 10226, 10225, 10224, 10223, 10222, 10221, 10220, 10219, 10218, 10217, 10216, + 10100, 10101, 10102, 10103, 10104, 10105, 10106, 10107, 10108, 10109, 10110, 10111, 10112, 10113, 10114, 10115, + // 10115, 10114, 10113, 10112, 10111, 10110, 10109, 10108, 10107, 10106, 10105, 10104, 10103, 10102, 10101, 10100, + 10300, 10301, 10302, 10303, 10304, 10305, 10306, 10307, 10308, 10309, 10310, 10311, 10312, 10313, 10314, 10315, + // 10315, 10314, 10313, 10312, 10311, 10310, 10309, 10308, 10307, 10306, 10305, 10304, 10303, 10302, 10301, 10300, + 10215, 10214, 10213, 10212, 10211, 10210, 10209, 10208, 10207, 10206, 10205, 10204, 10203, 10202, 10201, 10200, + //================== 15528 + 10316, 10317, 10318, 10319, 10320, 10321, 10322, 10323, 10324, 10325, 10326, 10327, 10328, 10329, 10330, 10331, + -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, + -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, + -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, + //================== 89 + // 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 + // 30004, -1, 30003, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, + //================== 334 + 20116, 20117, 20118, 20119, -1, 20121, 20122, 20123, 20016, 20017, 20018, -1, 20020, 20021, 20022, 20023, + //================== 379 + -1, 20001, 20002, 20003, 20004, 20005, -1, 20007, 20008, -1, 20010, 20011, 20012, 20013, 20014, 20015, + //================== 325 + 20100, 20101, 20102, 20103, 20104, 20105, 20106, 20107, 20108, 20109, 20110, 20111, 20112, -1, 20114, 20115, + //================== 405 + // 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 + 20006, -1, 30005, 20009, -1, 20120, 20000, 20019, 20113, 30000, 30004, 30001, 30002, -1, 30003, -1}; + +// MCP moved from channel 1 to 2 after Run number 322 +// MCP and Rf moved to ch 0 and 1 after Run number after Run282 +// moved back to ch +void PrintMapping() +{ + + int digiID = 0; + int count = 0; + printf("==================== ID-MAP: \n"); + printf("%11s|", ""); + for (int i = 0; i < 16; i++) + printf("%7d|", i); + printf("\n"); + for (int i = 0; i < 12 + 16 * 8; i++) + printf("-"); + for (size_t i = 0; i < mapping.size(); i++) + { + if ((i) % 16 == 0) + { + printf("\n"); + + if (digiID < nBd) + { + if (board.at(digiID) > 1000) + { + if (count == 3) + digiID++; + if (i % 64 == 0) + { + printf("%11d|", board.at(digiID)); + count = 0; + } + } + else + { + if (count == 1) + digiID++; + if (i % 16 == 0) + { + printf("%11d|", board.at(digiID)); + count = 0; + } + } + } + + if (count != 0) + printf("%11s|", ""); + count++; + } + + int typeID = mapping[i] / 10000; + int detID = (mapping[i] - typeID * 10000) / 100; + int ch = mapping[i] - typeID * 10000 - detID * 100; + + if (mapping[i] == -1) + { + + printf("%7s|", ""); + } + else + { + + if (typeID == 0) + { // SX3 + + printf("\033[36m%3d(%2d)\033[0m|", detID, ch); + } + else if (typeID == 1) + { // QQQ + + printf("\033[91m%3d(%2d)\033[0m|", detID, ch); + } + else if (typeID == 2) + { // PC + + printf("\033[35m%3d(%2d)\033[0m|", detID, ch); + } + else if (typeID == 3) + { // MISC + + printf("\033[33m%3d(%2d)\033[0m|", detID, ch); + } + } + } + printf("\n"); + for (int i = 0; i < 12 + 16 * 8; i++) + printf("-"); + printf("\n"); +} + +void GenMapping(std::string mapFile) +{ + + std::vector map; + + std::ifstream inputFile(mapFile); // Replace "your_file.txt" with the actual file path + + if (!inputFile.is_open()) + { + printf("Error: Could not open the file (%s).\n", mapFile.c_str()); + return; + } + + std::string line; + + // Read the file line by line + while (std::getline(inputFile, line)) + { + std::vector words; + std::istringstream iss(line); + + // Extract words from the current line + while (true) + { + std::string word; + if (!(iss >> word)) + break; // Break if there are no more words + + word.erase(std::remove_if(word.begin(), word.end(), ::isspace), word.end()); + words.push_back(word); + } + + if (atoi(words[0].c_str()) % 16 == 0) + printf("=================\n"); + + int detID = atoi(words[1].c_str()) * 100; + if (words.size() < 5) + printf(" hahhahha %s\n", line.c_str()); + if (words[2] == "BARREL") + { + if (words[3] == "FRONTDOWN") + { + int chID = atoi(words[4].c_str()); + if (chID % 2 != 0) + chID -= 1; + detID += chID; + } + + if (words[3] == "FRONTUP") + { + int chID = atoi(words[4].c_str()); + if (chID % 2 == 0) + chID += 1; + detID += chID; + } + + if (words[3] == "BACK") + detID += atoi(words[4].c_str()) + 8; + } + + if (words[2] == "FQQQ") + { + detID += 10000; + if (words[3] == "WEDGE") + detID += atoi(words[4].c_str()); + if (words[3] == "RING") + detID += atoi(words[4].c_str()) + 16; + } + + if (words[2] == "PC") + { + detID += 20000; + if (words[3] == "ANODE") + detID += atoi(words[4].c_str()); + if (words[3] == "CATHODE") + detID += 100 + atoi(words[4].c_str()); + } + + if (words[2] == "blank") + { + detID = -1; + } + + map.push_back(detID); + + printf("| %5d", detID); + printf("|\n"); + } + + // Close the file + inputFile.close(); + + int digiID = 0; + int count = 0; + printf("===============================\n"); + for (size_t i = 0; i < ((map.size() + 15) / 16) * 16; i++) + { + if (i % 16 == 0) + { + printf("\n"); + if (digiID < nBd) + { + if (board.at(digiID) > 1000) + { + if (count == 3) + digiID++; + if (i % 64 == 0) + { + printf(" //================== %d\n", board.at(digiID)); + count = 0; + } + } + else + { + if (count == 1) + digiID++; + if (i % 16 == 0) + { + printf(" //================== %d\n", board.at(digiID)); + count = 0; + } + } + } + count++; + } + if (i < map.size()) + { + printf(" %5d,", map[i]); + } + else + { + printf(" %5d,", -1); + } + } + printf("\n\n===============================\n"); + + printf("sorting mapping and see if there any repeated\n"); + std::sort(map.begin(), map.end()); + + for (size_t i = 1; i < map.size(); i++) + { + if (map[i] == -1) + continue; + if (map[i] == map[i - 1]) + printf("%5d \n", map[i]); + } + printf("=========== Done. if nothing show, no repeat. \n"); +} + +#endif diff --git a/anasen_analysis_vignesh/mapping_alpha.h b/anasen_analysis_vignesh/mapping_alpha.h new file mode 100644 index 0000000..288531b --- /dev/null +++ b/anasen_analysis_vignesh/mapping_alpha.h @@ -0,0 +1,274 @@ +#ifndef Mapping_h +#define Mapping_h + +#include +#include +#include +#include +#include +#include +#include + +#include + +const std::map board = { + {0, 17122}, // id, sn + {1, 17123}, + {2, 22320}, + {3, 22130}, + {4, 22129}, + {5, 15529}, + {6, 15528}, + {7, 334}, + {8, 409}, + {9, 405} +}; +const int nBd = board.size(); + +const int nV1740 = 7; +const int nV1725 = 3; + +//+++++++++++++++++++ detID; +// The detectors are seperated into 2 type: SuperX3, QQQ, and PC +// the SuperX3 has 24 detectors for each kind, wach detector has 12 channels +// the QQQ has 4 detectors for each kind, each detector has 32 channels +// the PC has 2 types, anode and cathode, each has 24 channels +// The detID = Type * 10000 + index * 100 + channel +// fro example, detID(superX3-8, ch-7) = 00807 + + +// use the GenMapping() to get that +const std::vector mapping = { + + //================== 17122 + 806, 807, 804, 805, 803, 802, 801, 800, 1006, 1007, 1004, 1005, 1003, 1002, 1001, 1000, + 606, 607, 604, 605, 603, 602, 601, 600, 1106, 1107, 1104, 1105, 1103, 1102, 1101, 1100, + 711, 710, 709, 708, 911, 910, 909, 908, 811, 810, 809, 808, 1011, 1010, 1009, 1008, + 706, 707, 704, 705, 703, 702, 701, 700, 906, 907, 904, 905, 903, 902, 901, 900, + //================== 17123 + 1406, 1407, 1404, 1405, 1403, 1402, 1401, 1400, 1606, 1607, 1604, 1605, 1603, 1602, 1601, 1600, + 1306, 1307, 1304, 1305, 1303, 1302, 1301, 1300, 1506, 1507, 1504, 1505, 1503, 1502, 1501, 1500, + 1311, 1310, 1309, 1308, 1511, 1510, 1509, 1508, 1411, 1410, 1409, 1408, 1611, 1610, 1609, 1608, + 1206, 1207, 1204, 1205, 1203, 1202, 1201, 1200, 1706, 1707, 1704, 1705, 1703, 1702, 1701, 1700, + //================== 22320 + 111, 110, 109, 108, 311, 310, 309, 308, 411, 410, 409, 408, 211, 210, 209, 208, + 6, 7, 4, 5, 3, 2, 1, 0, 506, 507, 504, 505, 503, 502, 501, 500, + 206, 207, 204, 205, 203, 202, 201, 200, 406, 407, 404, 405, 403, 402, 401, 400, + 106, 107, 104, 105, 103, 102, 101, 100, 306, 307, 304, 305, 303, 302, 301, 300, + //================== 22130 + 1911, 1910, 1909, 1908, 2111, 2110, 2109, 2108, 2211, 2210, 2209, 2208, 2011, 2010, 2009, 2008, + 11, 10, 9, 8, 511, 510, 509, 508, 611, 610, 609, 608, 1111, 1110, 1109, 1108, + 2006, 2007, 2004, 2005, 2003, 2002, 2001, 2000, 2206, 2207, 2204, 2205, 2203, 2202, 2201, 2200, + 1906, 1907, 1904, 1905, 1903, 1902, 1901, 1900, 2106, 2107, 2104, 2105, 2103, 2102, 2101, 2100, + //================== 22129 + 10016, 10017, 10018, 10019, 10020, 10021, 10022, 10023, 10024, 10025, 10026, 10027, 10028, 10029, 10030, 10031, + 1806, 1807, 1804, 1805, 1803, 1802, 1801, 1800, 2306, 2307, 2304, 2305, 2303, 2302, 2301, 2300, + 10116, 10117, 10118, 10119, 10120, 10121, 10122, 10123, 10124, 10125, 10126, 10127, 10128, 10129, 10130, 10131, + 10115, 10114, 10113, 10112, 10111, 10110, 10109, 10108, 10107, 10106, 10105, 10104, 10103, 10102, 10101, 10100, + //================== 15529 + 10316, 10317, 10318, 10319, 10320, 10321, 10322, 10323, 10324, 10325, 10326, 10327, 10328, 10329, 10330, 10331, + 10015, 10014, 10013, 10012, 10011, 10010, 10009, 10008, 10007, 10006, 10005, 10004, 10003, 10002, 10001, 10000, + 10315, 10314, 10313, 10312, 10311, 10310, 10309, 10308, 10307, 10306, 10305, 10304, 10303, 10302, 10301, 10300, + 10215, 10214, 10213, 10212, 10211, 10210, 10209, 10208, 10207, 10206, 10205, 10204, 10203, 10202, 10201, 10200, + //================== 15528 + 10216, 10217, 10218, 10219, 10220, 10221, 10222, 10223, 10224, 10225, 10226, 10227, 10228, 10229, 10230, 10231, + -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, + -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, + -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, + //================== 334 + 20116, 20117, 20118, 20119, 20120, 20121, 20122, 20123, 20016, 20017, 20018, 20019, 20020, 20021, 20022, 20023, + //================== 409 + 20000, 20001, 20002, 20003, 20004, 20005, 20006, 20007, 20008, 20009, 20010, 20011, 20012, 20013, 20014, 20015, + //================== 405 + 20100, 20101, 20102, 20103, 20104, 20105, 20106, 20107, 20108, 20109, 20110, 20111, 20112, 20113, 20114, 20115 + +}; + +void PrintMapping(){ + + int digiID = 0; + int count = 0; + printf("==================== ID-MAP: \n"); + printf("%11s|", ""); for(int i = 0 ; i < 16; i++ ) printf("%7d|", i); + printf("\n"); + for(int i = 0 ; i < 12 + 16*8; i++ ) printf("-"); + for(size_t i = 0 ; i < mapping.size(); i ++){ + if( (i) % 16 == 0 ) { + printf("\n"); + + if( digiID < nBd ){ + if( board.at(digiID) > 1000 ) { + if( count == 3 ) digiID ++; + if( i % 64 == 0 ) { + printf("%11d|", board.at(digiID)); + count = 0; + } + }else{ + if( count == 1 ) digiID ++; + if( i % 16 == 0 ) { + printf("%11d|", board.at(digiID)); + count = 0; + } + } + } + + if( count != 0) printf("%11s|", ""); + count ++; + } + + int typeID = mapping[i] / 10000; + int detID = (mapping[i] - typeID*10000 )/100; + int ch = mapping[i] - typeID*10000 - detID * 100; + + if( mapping[i] == -1 ) { + + printf("%7s|", ""); + + }else{ + + if( typeID == 0){ // SX3 + + printf("\033[36m%3d(%2d)\033[0m|", detID, ch); + + }else if( typeID == 1){ // QQQ + + printf("\033[91m%3d(%2d)\033[0m|", detID, ch); + + }else if( typeID == 2){ // PC + + printf("\033[35m%3d(%2d)\033[0m|", detID, ch); + + }else{ + + + } + } + } + printf("\n"); + for(int i = 0 ; i < 12 + 16*8; i++ ) printf("-"); + printf("\n"); + +} + + +void GenMapping(std::string mapFile){ + + + std::vector map; + + + std::ifstream inputFile(mapFile); // Replace "your_file.txt" with the actual file path + + if (!inputFile.is_open()) { + printf("Error: Could not open the file (%s).\n", mapFile.c_str()); + return ; + } + + std::string line; + + // Read the file line by line + while (std::getline(inputFile, line)) { + std::vector words; + std::istringstream iss(line); + + // Extract words from the current line + while (true) { + std::string word; + if (!(iss >> word)) break; // Break if there are no more words + + word.erase(std::remove_if(word.begin(), word.end(), ::isspace), word.end()); + words.push_back(word); + + } + + if( atoi(words[0].c_str()) % 16 == 0 ) printf("=================\n"); + + + int detID = atoi(words[1].c_str())*100; + if(words.size() < 5 ) printf(" hahhahha %s\n", line.c_str()); + if( words[2] == "BARREL" ) { + if( words[3] == "FRONTDOWN" ){ + int chID = atoi(words[4].c_str()); + if( chID % 2 != 0 ) chID -= 1; + detID += chID; + } + + if( words[3] == "FRONTUP" ){ + int chID = atoi(words[4].c_str()); + if( chID % 2 == 0 ) chID += 1; + detID += chID; + } + + if( words[3] == "BACK") detID += atoi(words[4].c_str()) + 8; + } + + if( words[2] == "FQQQ" ) { + detID += 10000; + if( words[3] == "WEDGE") detID += atoi(words[4].c_str()); + if( words[3] == "RING") detID += atoi(words[4].c_str()) + 16; + } + + if( words[2] == "PC" ) { + detID += 20000; + if( words[3] == "ANODE") detID += atoi(words[4].c_str()); + if( words[3] == "CATHODE") detID += 100 + atoi(words[4].c_str()); + + } + + if( words[2] == "blank") { + detID = -1; + } + + map.push_back(detID); + + printf("| %5d", detID); + printf("|\n"); + } + + // Close the file + inputFile.close(); + + int digiID = 0; + int count = 0; + printf("===============================\n"); + for( size_t i = 0; i < ((map.size() +15)/16) * 16; i++){ + if( i % 16 == 0) { + printf("\n"); + if( digiID < nBd ){ + if( board.at(digiID) > 1000 ) { + if( count == 3 ) digiID ++; + if( i % 64 == 0 ) { + printf(" //================== %d\n", board.at(digiID)); + count = 0; + } + }else{ + if( count == 1 ) digiID ++; + if( i % 16 == 0 ) { + printf(" //================== %d\n", board.at(digiID)); + count = 0; + } + } + } + count ++; + } + if( i < map.size() ){ + printf(" %5d,", map[i]); + }else{ + printf(" %5d,", -1); + } + } + printf("\n\n===============================\n"); + + printf("sorting mapping and see if there any repeated\n"); + std::sort(map.begin(), map.end()); + + for( size_t i = 1; i < map.size(); i++){ + if( map[i] == -1 ) continue; + if( map[i] == map[i-1] ) printf("%5d \n", map[i]); + } + printf("=========== Done. if nothing show, no repeat. \n"); + + +} + +#endif \ No newline at end of file diff --git a/anasen_analysis_vignesh/pccal/anode_gainmatch.C b/anasen_analysis_vignesh/pccal/anode_gainmatch.C new file mode 100644 index 0000000..fa267be --- /dev/null +++ b/anasen_analysis_vignesh/pccal/anode_gainmatch.C @@ -0,0 +1,67 @@ +void anode_gainmatch(){ + TFile *f = new TFile("../results_run16.root"); + + TH2F *pc_index_h2d = (TH2F*)(f->Get("hRawPC/PC_Index_Vs_Energy")); + std::cout << pc_index_h2d << std::endl; + TCanvas c("c1","c1",0,0,1600,800); + //TCanvas c_g("cg","cg",0,900,400,400); + c.Divide(2,1); + auto c1=c.cd(1); + pc_index_h2d->Draw("COLZ"); + pc_index_h2d->GetYaxis()->SetRangeUser(240,5000); + auto c2=c.cd(2); + c2->SetLogy(); + TH1F *h_1d=NULL; + int bin_index=1; + std::vector> all_peaks; + std::vector found_wire_list; + while(bin_index<=24) { + h_1d=(TH1F*)(pc_index_h2d->ProjectionY("_py",bin_index,bin_index)); + auto c1 = c.cd(1); + TBox box(pc_index_h2d->GetXaxis()->GetBinLowEdge(bin_index),0,pc_index_h2d->GetXaxis()->GetBinUpEdge(bin_index),pc_index_h2d->GetYaxis()->GetXmax()); + box.SetFillColorAlpha(kYellow+3,0.3); + box.Draw("SAME"); + c1->Modified(); c1->Update(); + //while(c1->WaitPrimitive()); + + TSpectrum s; + auto c2 = c.cd(2); + h_1d->Draw(); + c2->Modified(); c2->Update(); + int npeaks = s.Search(h_1d,8,"",0.02); std::cout << npeaks << std::endl; + if(npeaks>=3) { + std::vector xpeaks(s.GetPositionX(),s.GetPositionX()+npeaks); + std::sort(xpeaks.begin(),xpeaks.end(),std::greater()); + found_wire_list.push_back((int)pc_index_h2d->GetXaxis()->GetBinCenter(bin_index)); + all_peaks.push_back(xpeaks); + } + while(c2->WaitPrimitive()); + bin_index++; + } + c.cd(2)->SetLogy(kFALSE); + gStyle->SetOptFit(1111); + + std::ofstream outfile("anode_gm_coeffs.dat"); + outfile << found_wire_list.at(0) << " " + << 1.0 << " " + << 0.0 << std::endl; + + for(int i=0; iGetParameter(1) << " " + << ((TF1*)g.FindObject("pol1"))->GetParameter(0) << std::endl; + c2->Modified(); + c2->Update(); + while(c2->WaitPrimitive()); + } + outfile.close(); + f->Close(); + return; +} diff --git a/anasen_analysis_vignesh/pccal/anode_gm_coeffs.dat b/anasen_analysis_vignesh/pccal/anode_gm_coeffs.dat new file mode 100644 index 0000000..a241cfe --- /dev/null +++ b/anasen_analysis_vignesh/pccal/anode_gm_coeffs.dat @@ -0,0 +1,24 @@ +0 1 0 +0 0.937314 -16.871 +2 0.965461 -1.54376 +3 0.926501 -3.27662 +4 0.905634 2.54577 +5 0.905634 -11.0387 +6 0.853919 6.23079 +7 0.945588 -9.54044 +8 0.884454 -11.8262 +9 0.922501 -3.42538 +10 0.903053 9.28069 +11 0.914653 9.87642 +12 0.965332 13.2526 +13 0.923847 -3.41775 +14 0.93845 25.9901 +15 0.955424 12.324 +16 0.95116 4.99595 +17 0.910745 2.86648 +18 0.941376 4.57217 +19 0.871622 932.111 +20 1.00624 7.86358 +21 0.969834 -45.001 +22 0.89304 -31.5635 +23 0.933226 4.02193 diff --git a/anasen_analysis_vignesh/pccal/cathode_gainmatch.C b/anasen_analysis_vignesh/pccal/cathode_gainmatch.C new file mode 100644 index 0000000..d52e32a --- /dev/null +++ b/anasen_analysis_vignesh/pccal/cathode_gainmatch.C @@ -0,0 +1,69 @@ +void cathode_gainmatch(){ + TFile *f = new TFile("../results_run17.root"); + TH2F *pc_index_h2d = (TH2F*)(f->Get("hRawPC/PC_Index_Vs_Energy")); + std::cout << pc_index_h2d << std::endl; + TCanvas c("c1","c1",0,0,1600,800); + //TCanvas c_g("cg","cg",0,900,400,400); + c.Divide(2,1); + auto c1=c.cd(1); + pc_index_h2d->Draw("COLZ"); + pc_index_h2d->GetYaxis()->SetRangeUser(600,pc_index_h2d->GetYaxis()->GetXmax()); + auto c2=c.cd(2); + c2->SetLogy(); + TH1F *h_1d=NULL; + int bin_index=25; + std::vector pulser_heights = {0.01,0.05,0.1,0.15,0.2,0.25,0.3,0.5}; + std::vector> all_peaks; + std::vector found_wire_list; + while(bin_index<=48) { + h_1d=(TH1F*)(pc_index_h2d->ProjectionY("_py",bin_index,bin_index)); + auto c1 = c.cd(1); + TBox box(pc_index_h2d->GetXaxis()->GetBinLowEdge(bin_index),0,pc_index_h2d->GetXaxis()->GetBinUpEdge(bin_index),pc_index_h2d->GetYaxis()->GetXmax()); + box.SetFillColorAlpha(kYellow+3,0.3); + box.Draw("SAME"); + c1->Modified(); c1->Update(); + //while(c1->WaitPrimitive()); + + TSpectrum s; + auto c2 = c.cd(2); + h_1d->Draw(); + c2->Modified(); c2->Update(); + int npeaks = s.Search(h_1d,20,"",0.1); std::cout << npeaks << std::endl; + if(npeaks==8) { + std::vector xpeaks(s.GetPositionX(),s.GetPositionX()+npeaks); + for(int i=0; i<8; i++) { + std::cout << pc_index_h2d->GetXaxis()->GetBinCenter(bin_index) << " " << xpeaks.at(i) << " " << xpeaks.at(i)/pulser_heights.at(i) << std::endl; + } + std::sort(xpeaks.begin(),xpeaks.end(),std::greater()); + found_wire_list.push_back((int)pc_index_h2d->GetXaxis()->GetBinCenter(bin_index)); + all_peaks.push_back(xpeaks); + } + while(c2->WaitPrimitive()); + bin_index++; + } + c.cd(2)->SetLogy(kFALSE); + gStyle->SetOptFit(1111); + + std::ofstream outfile("cathode_gm_coeffs.dat"); + outfile << found_wire_list.at(0) << " " + << 1.0 << " " + << 0.0 << std::endl; + + for(int i=1; iGetParameter(1) << " " + << ((TF1*)g.FindObject("pol1"))->GetParameter(0) << std::endl; + c2->Modified(); + c2->Update(); + while(c2->WaitPrimitive()); + } + outfile.close(); + f->Close(); + return; +} diff --git a/anasen_analysis_vignesh/pccal/cathode_gm_coeffs.dat b/anasen_analysis_vignesh/pccal/cathode_gm_coeffs.dat new file mode 100644 index 0000000..b1aaa77 --- /dev/null +++ b/anasen_analysis_vignesh/pccal/cathode_gm_coeffs.dat @@ -0,0 +1,21 @@ +24 1 0 +25 0.941896 6.16135 +26 0.980284 2.86886 +27 0.983166 -3.82952 +28 0.978704 -2.89713 +29 0.964947 2.25786 +30 0.94514 0.925074 +31 0.977231 1.6493 +32 0.919527 5.82742 +33 0.972243 2.88061 +34 0.928892 7.61384 +35 0.947376 -0.644223 +36 0.875342 6.066 +38 0.970953 6.262 +40 0.918408 -3.27891 +41 0.913619 4.11288 +42 0.954083 2.21261 +43 0.993037 5.48924 +45 0.926406 -19.719 +46 1.00459 5.14574 +47 0.942483 5.54183 diff --git a/anasen_analysis_vignesh/pccal/pc_gm_coeffs.dat b/anasen_analysis_vignesh/pccal/pc_gm_coeffs.dat new file mode 100644 index 0000000..92d002f --- /dev/null +++ b/anasen_analysis_vignesh/pccal/pc_gm_coeffs.dat @@ -0,0 +1,49 @@ +#Histogram Number Slope Intercept +0 0.937314 -16.871 +1 0 0 +2 0.965461 -1.54376 +3 0.926501 -3.27662 +4 0.905634 2.54577 +5 0.905634 -11.0387 +6 0.853919 6.23079 +7 0.945588 -9.54044 +8 0.884454 -11.8262 +9 0.922501 -3.42538 +10 0.903053 9.28069 +11 0.914653 9.87642 +12 0.965332 13.2526 +13 0.923847 -3.41775 +14 0.93845 25.9901 +15 0.955424 12.324 +16 0.95116 4.99595 +17 0.910745 2.86648 +18 0.941376 4.57217 +19 0.871622 932.111 +20 1.00624 7.86358 +21 0.969834 -45.001 +22 0.89304 -31.5635 +23 0.933226 4.02193 +24 0 0 +25 0.941896 6.16135 +26 0.980284 2.86886 +27 0.983166 -3.82952 +28 0.978704 -2.89713 +29 0.964947 2.25786 +30 0.94514 0.925074 +31 0.977231 1.6493 +32 0.919527 5.82742 +33 0.972243 2.88061 +34 0.928892 7.61384 +35 0.947376 -0.644223 +36 0.875342 6.066 +37 0 0 +38 0.970953 6.262 +39 0 0 +40 0.918408 -3.27891 +41 0.913619 4.11288 +42 0.954083 2.21261 +43 0.993037 5.48924 +44 0 0 +45 0.926406 -19.719 +46 1.00459 5.14574 +47 0.942483 5.54183 diff --git a/anasen_analysis_vignesh/pccal/slope_intercept_26Al.dat b/anasen_analysis_vignesh/pccal/slope_intercept_26Al.dat new file mode 100644 index 0000000..875aaec --- /dev/null +++ b/anasen_analysis_vignesh/pccal/slope_intercept_26Al.dat @@ -0,0 +1,50 @@ +#Histogram Number Slope Intercept +#Histogram Number Slope Intercept +0 0.931015 -1.35431 +1 1 -1.87356e-10 +2 0.964185 1.49989 +3 0.92638 -1.30621 +4 0.905569 1.00834 +5 0.901182 0.470903 +6 0.853932 3.32687 +7 0.942785 1.08887 +8 0.878904 -0.0107433 +9 0.922662 -2.32259 +10 0.903343 8.38332 +11 0.914227 6.56108 +12 0.961008 23.0982 +13 0.920976 5.22104 +14 0.936584 31.5073 +15 0.959044 5.43267 +16 0.95263 -0.404053 +17 0.90953 4.82833 +18 0.940277 10.3629 +19 0.86746 -17.8678 +20 1.00683 4.76371 +21 0.968342 -43.9496 +22 0.892882 -32.0742 +23 0.933615 1.10704 +24 1 -2.89219e-10 +25 0.942098 -0.105169 +26 0.980862 -0.732032 +27 0.982975 -2.22704 +28 0.978815 -1.51477 +29 0.965245 -2.19515 +30 0.945384 -0.892599 +31 0.977408 -0.908592 +32 0.919546 3.25464 +33 0.972194 2.44956 +34 0.92852 5.44745 +35 0.947098 1.40531 +36 0.875491 -1.13145 +37 1 0 +38 0.970862 2.86019 +39 1 0 +40 0.91793 -3.80615 +41 0.913897 -2.12964 +42 0.954014 -0.760604 +43 0.993616 -1.40278 +44 1 0 +45 0.926169 -21.2016 +46 1.00577 -2.14281 +47 0.943312 -1.26464 diff --git a/anasen_analysis_vignesh/processRun.C b/anasen_analysis_vignesh/processRun.C new file mode 100644 index 0000000..a2b96cb --- /dev/null +++ b/anasen_analysis_vignesh/processRun.C @@ -0,0 +1,15 @@ +#include "TFile.h" +#include "TString.h" +#include "TROOT.h" +#include "TTree.h" + + +void processRun(TString runFile){ + + TFile * file = new TFile(runFile); + + TTree * tree = (TTree *) file->Get("tree"); + + tree->Process("Analyzer.C+"); + +} \ No newline at end of file diff --git a/anasen_analysis_vignesh/qqq_Calib.dat b/anasen_analysis_vignesh/qqq_Calib.dat new file mode 100644 index 0000000..99bbc7f --- /dev/null +++ b/anasen_analysis_vignesh/qqq_Calib.dat @@ -0,0 +1,760 @@ +0 0 0 3.34288 +0 1 0 3.29257 +0 2 0 3.31126 +0 3 0 3.28022 +0 4 0 3.29877 +0 5 0 3.29877 +0 6 0 3.305 +0 7 0 3.305 +0 8 0 3.26797 +0 9 0 3.32384 +0 10 0 3.31126 +0 11 0 3.32384 +0 12 0 3.29877 +0 13 0 3.31126 +0 14 0 3.28022 +0 15 0 3.27409 +0 0 2 3.44828 +0 1 2 3.53179 +0 2 2 3.53179 +0 3 2 3.44149 +0 4 2 3.48259 +0 5 2 3.47567 +0 6 2 3.48953 +0 7 2 3.45508 +0 8 2 3.46878 +0 9 2 3.46192 +0 10 2 3.45508 +0 11 2 3.46192 +0 12 2 3.48259 +0 13 2 3.5035 +0 14 2 3.4965 +0 15 2 3.46878 +0 0 3 3.2022 +0 1 3 3.20807 +0 2 3 3.23176 +0 3 3 3.23176 +0 4 3 3.23774 +0 5 3 3.20807 +0 6 3 3.19635 +0 7 3 3.21987 +0 8 3 3.18471 +0 9 3 3.21396 +0 10 3 3.19635 +0 11 3 3.20807 +0 12 3 3.18471 +0 13 3 3.22581 +0 14 3 3.19635 +0 15 3 3.19635 +0 0 4 3.33016 +0 1 4 3.32384 +0 2 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0.959995 0 +3 15 15 0.98169 0 diff --git a/anasen_analysis_vignesh/results/run_12_fixed_geometry2_13Feb26.pdf b/anasen_analysis_vignesh/results/run_12_fixed_geometry2_13Feb26.pdf new file mode 100644 index 0000000..561ad74 Binary files /dev/null and b/anasen_analysis_vignesh/results/run_12_fixed_geometry2_13Feb26.pdf differ diff --git a/anasen_analysis_vignesh/results/run_12_fixed_geometry_13Feb26.pdf b/anasen_analysis_vignesh/results/run_12_fixed_geometry_13Feb26.pdf new file mode 100644 index 0000000..3c87f7e Binary files /dev/null and b/anasen_analysis_vignesh/results/run_12_fixed_geometry_13Feb26.pdf differ diff --git a/anasen_analysis_vignesh/rootlogon.C b/anasen_analysis_vignesh/rootlogon.C new file mode 100644 index 0000000..1d23fdd --- /dev/null +++ b/anasen_analysis_vignesh/rootlogon.C @@ -0,0 +1,3 @@ +{ + gSystem->SetBuildDir("./obj/",1); +} diff --git a/anasen_analysis_vignesh/run.sh b/anasen_analysis_vignesh/run.sh new file mode 100755 index 0000000..5bd961f --- /dev/null +++ b/anasen_analysis_vignesh/run.sh @@ -0,0 +1,3 @@ +#!/bin/bash +outfile="$2_output/results_run$1.root" +root -q -l -b -x ../ANASEN_analysis/data/$2_Data/Run_$1_mapped.root -e $(printf 'tree->Process("MakeVertex.C+O","%s")' $outfile); diff --git a/anasen_analysis_vignesh/run_17F.sh b/anasen_analysis_vignesh/run_17F.sh new file mode 100644 index 0000000..b3758c5 --- /dev/null +++ b/anasen_analysis_vignesh/run_17F.sh @@ -0,0 +1,46 @@ +rm results_run*.root +export DATASET="17F" +export flip180="0" +export flipa=0 +export anode_offset=1 +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_005_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run05.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_006_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run06.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_007_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run07.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_008_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run08.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_009_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run09.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_010_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run10.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_011_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run11.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_012_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run12.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_013_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run13.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_014_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run14.root; + +#17F pulser runs +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/PulserRun_015_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run15.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/PulserRun_016_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run16.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/PulserRun_017_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run17.root; + +#17F alpha run with gas +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_018_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run18.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_019_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run19.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_020_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run20.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_021_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run21.root; + +#17F reaction data +export flip180="1" +declare -i run=231 #49 +while [[ $run -lt 235 ]]; do #392 + wrun=$(printf "%03d" $run) + file_exists=$(test -f ../ANASEN_analysis/data/17F_Data/Run_"$wrun"_mapped.root) + if [[ $file_exists -ne 0 ]]; then continue; fi + root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Run_"$wrun"_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run$wrun.root; + run=run+1 +done + +rm output_17F.root +hadd -j 4 -k output_17F.root results_run2*.root + +unset souce_vertex +unset DATASET +unset flip180 +unset flipa +unset anode_offset diff --git a/anasen_analysis_vignesh/run_19_22.sh b/anasen_analysis_vignesh/run_19_22.sh new file mode 100644 index 0000000..1f9d6fc --- /dev/null +++ b/anasen_analysis_vignesh/run_19_22.sh @@ -0,0 +1,33 @@ +#Alpha runs at different spacer positions +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_009_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_09.root; +###root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_010_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_10.root; +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_012_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_12.root; +#root -l -x Analyzer_QQQ_09.root Analyzer_QQQ_12.root -e "new TBrowser" + +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_009_mapped.root -e 'tree->Process("DataDump.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_09.root; + +#26Al runs +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_027_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_27.root; +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_028_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_28.root; +# root -l -x Analyzer_QQQ_27.root Analyzer_QQQ_28.root -e "new TBrowser" + + +#Proton runs at different spacer positions 26Al +root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_019_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_SX3.root results_run19.root; +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_021_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_21.root; +root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_022_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_SX3.root results_run22.root; +root -l -x results_run19.root results_run22.root + +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_084_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_SX3.root results_run84.root; +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_078_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_SX3.root results_run78.root; +#root -l -x results_run84.root -e "new TBrowser" + +#root -q -l -x ../ANASEN_analysis/data/27Al_Data/ProtonRun_032_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_SX3.root results_run32.root; +#root -l -x results_run32.root -e "new TBrowser" + + +#root -q -l -x ../ANASEN_analysis/data/17F_Data/ProtonRun_022_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_22.root; +#root -q -l -x ../ANASEN_analysis/data/17F_Data/ProtonRun_025_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_25.root; +#root -q -l -x ../ANASEN_analysis/data/17F_Data/ProtonRun_026_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_26.root; +#root -q -l -x ../ANASEN_analysis/data/17F_Data/ProtonRun_027_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_27.root; +#root -q -l -x ../ANASEN_analysis/data/17F_Data/ProtonRun_028_mapped.root -e 'tree->Process("MakeVertex.C+")'; mv Analyzer_QQQ.root Analyzer_QQQ_28.root; diff --git a/anasen_analysis_vignesh/run_27Al.sh b/anasen_analysis_vignesh/run_27Al.sh new file mode 100644 index 0000000..378f819 --- /dev/null +++ b/anasen_analysis_vignesh/run_27Al.sh @@ -0,0 +1,28 @@ +#rm results_run*.root +export DATASET="27Al" +export flip180="0" +#declare -i run=28 +#while [[ $run -lt 34 ]]; do #runs 1 to 84 +# wrun=$(printf "%03d" $run) +# root -q -l -b -x ../ANASEN_analysis/data/27Al_Data/Run_"$wrun"_mapped.root -e 'tree->Process("Make#Vertex.C+O")'; mv Analyzer_SX3.root 27Al_output/results_run$wrun.root; +# run=run+1 +#done + +declare -i run=50 +while [[ $run -lt 59 ]]; do #runs 1 to 84 + wrun=$(printf "%03d" $run) + root -q -l -b -x ../ANASEN_analysis/data/27Al_Data/Run_"$wrun"_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root 27Al_output/results_run$wrun.root; + run=run+1 +done + +rm output.root +hadd -k -j 4 output.root 27Al_output/results_run*.root +mv output.root output_27Al.root + +#root -q -l -b -x -e '.L MakeVertex.C+O'; +#halfproc=3 +#parallel --ctag --bar -j $halfproc ./run.sh ::: {028..034} ::: 27Al #color-tag, linebuffer, then run run.sh in parallel + +unset souce_vertex +unset DATASET +unset flip180 diff --git a/anasen_analysis_vignesh/run_sx3.sh b/anasen_analysis_vignesh/run_sx3.sh new file mode 100644 index 0000000..f133085 --- /dev/null +++ b/anasen_analysis_vignesh/run_sx3.sh @@ -0,0 +1,104 @@ +#Alpha runs at different spacer positions +#rm results_run*.root +#export flipa=1 +export anode_offset=1 +export DATASET="27Al" +if [[ 1 -eq 0 ]]; then +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_009_mapped.root -e 'tree->Process("MakeVertex.C+O","27Al")'; mv Analyzer_SX3.root results_run09.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_001_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run01.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_002_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run02.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_003_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run03.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_004_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run04.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_005_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run05.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_006_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run06.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_007_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run07.root; +root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_008_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run08.root; +fi + +#exit +#alpha+gas 27Al +export DATASET="27Al" +export flip180="0" +#root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_009_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run09.root; +if [[ 1 -eq 0 ]]; then +#export timecut_low=500.0; +#export timecut_high=500.0; +#unset timecut_low, timecut_high +#export source_vertex=53.44; root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_009_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run09.root; +#export source_vertex=53.44; root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_010_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run10.root; +#export source_vertex=53.44; root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_011_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run11.root; +export source_vertex=53.44; root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_012_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run12.root; +#export source_vertex=53.44; root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_013_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run13.root; +#exit +fi + +#protons+gas, 27Al +#export flip180="1" +#export flip180="0" +if [[ 1 -eq 1 ]] ; then +export anode_offset=1 +root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_015_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run15.root; +root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_017_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run17.root; +root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_018_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run18.root; +root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_019_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run19.root; +root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_020_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run20.root; +root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_021_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run21.root; +root -q -b -x ../ANASEN_analysis/data/27Al_Data/Run_022_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run22.root; +exit +fi + +#27Al reaction data +#root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_051_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run51.root; +#root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_078_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run78.root; +#root -b -q -l -x ../ANASEN_analysis/data/27Al_Data/Run_081_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run81.root; + +#root -l -x results_run19.root results_run12.root -e "new TBrowser" +#exit +export DATASET="17F" +export flip180="0" +if [[ 1 -eq 0 ]]; then +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_005_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run05.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_006_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run06.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_007_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run07.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_008_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run08.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_009_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run09.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_010_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run10.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_011_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run11.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_012_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run12.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_013_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run13.root; +root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Source_014_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run14.root; +fi +#17F pulser runs +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/PulserRun_015_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run15.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/PulserRun_016_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run16.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/PulserRun_017_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run17.root; + +#17F alpha run with gas +export source_vertex=53.44; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_018_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run18.root; +export source_vertex=14.24; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_019_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run19.root; +export source_vertex=-24.96; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_020_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run20.root; +export source_vertex=-73.96; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/SourceRun_021_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run21.root; + +#17F reaction data +export flip180="1" +#export source_vertex=-57.28; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_035_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run35.root; +#export source_vertex=-8.28; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_036_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root resulrs_run36.root; +#export source_vertex=-27.88; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_037_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run37.root; +#export source_vertex=11.32; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_038_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run38.root; +#export source_vertex=30.92; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_039_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run39.root; +#export source_vertex=50.52; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_041_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run41.root; +#export source_vertex=70.12; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_042_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run42.root; +#export source_vertex=109.32; root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_043_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run43.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/ProtonRun_043_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run43.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Run_099_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run99.root; +#root -q -l -b -x ../ANASEN_analysis/data/17F_Data/Run_104_mapped.root -e 'tree->Process("MakeVertex.C+O")'; mv Analyzer_SX3.root results_run104.root; +#mv Analyzer_SX3.root results_run19.root; + +unset flipa +unset flipc +unset anode_offset +unset cathode_offset +unset souce_vertex +unset DATASET +unset flip180 +unset timecut_low, timecut_high diff --git a/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/compare.C b/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/compare.C new file mode 100644 index 0000000..d4d398e --- /dev/null +++ b/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/compare.C @@ -0,0 +1,41 @@ +#include +int quit=0; +void handler(int signal){ quit=1;} +void compare() { + signal(SIGINT,handler); + TCanvas c; + c.SetLogz(); + TFile f18("../../results_run18.root"); + TFile f19("../../results_run19.root"); + TFile f20("../../results_run20.root"); + TFile f21("../../results_run21.root"); + TH2F *h18 = (TH2F*)(f18.Get("pcz_vs_sx3z")); + TH2F *h19 = (TH2F*)(f19.Get("pcz_vs_sx3z")); + TH2F *h20 = (TH2F*)(f20.Get("pcz_vs_sx3z")); + TH2F *h21 = (TH2F*)(f21.Get("pcz_vs_sx3z")); + + h18->GetYaxis()->SetRangeUser(-200,200); + h19->GetYaxis()->SetRangeUser(-200,200); + h20->GetYaxis()->SetRangeUser(-200,200); + h21->GetYaxis()->SetRangeUser(-200,200); + h18->GetXaxis()->SetRangeUser(0,100); + h19->GetXaxis()->SetRangeUser(0,100); + h20->GetXaxis()->SetRangeUser(0,100); + h21->GetXaxis()->SetRangeUser(0,100); + + while(!quit) { + h18->Draw("COLZ"); + gPad->Modified(); gPad->Update(); while(gPad->WaitPrimitive()); + h19->Draw("COLZ"); + gPad->Modified(); gPad->Update(); while(gPad->WaitPrimitive()); + h20->Draw("COLZ"); + gPad->Modified(); gPad->Update(); while(gPad->WaitPrimitive()); + h21->Draw("COLZ"); + gPad->Modified(); gPad->Update(); while(gPad->WaitPrimitive()); + } + + f18.Close(); + f19.Close(); + f20.Close(); + f21.Close(); +} diff --git a/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/fit.log b/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/fit.log new file mode 100644 index 0000000..b2bd6fd --- /dev/null +++ b/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/fit.log @@ -0,0 +1,279 @@ + + +******************************************************************************* +Wed Mar 25 17:10:21 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 4 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +Warning: Initial value of parameter 'B' is zero. +iter chisq delta/lim lambda A B + 0 3.7754834810e+03 0.00e+00 2.97e+01 1.000000e+00 1.000000e-30 +BREAK: Singular matrix in Invert_RtR + +******************************************************************************* +Wed Mar 25 17:10:29 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 4 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +iter chisq delta/lim lambda A B + 0 3.5907054810e+03 0.00e+00 2.97e+01 1.000000e+00 1.000000e+00 + 5 9.9465658244e+01 -1.35e-03 2.97e-04 1.682744e+00 4.503012e+01 + +After 5 iterations the fit converged. +final sum of squares of residuals : 99.4657 +rel. change during last iteration : -1.34817e-08 + +degrees of freedom (FIT_NDF) : 2 +rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 7.05215 +variance of residuals (reduced chisquare) = WSSR/ndf : 49.7328 + +Final set of parameters Asymptotic Standard Error +======================= ========================== +A = 1.68274 +/- 0.1265 (7.517%) +B = 45.0301 +/- 5.311 (11.79%) + +correlation matrix of the fit parameters: + A B +A 1.000 +B 0.748 1.000 + + +******************************************************************************* +Wed Mar 25 17:14:06 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 4 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +Warning: Initial value of parameter 'B' is zero. +iter chisq delta/lim lambda A B + 0 3.7754834810e+03 0.00e+00 3.38e+01 1.000000e+00 1.000000e-30 +BREAK: Singular matrix in Invert_RtR + +******************************************************************************* +Wed Mar 25 17:14:13 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 4 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +iter chisq delta/lim lambda A B + 0 3.9682614810e+03 0.00e+00 3.38e+01 1.000000e+00 1.000000e+00 + 5 3.4734096263e+01 -3.36e-04 3.38e-04 5.876258e-01 -2.681171e+01 + +After 5 iterations the fit converged. +final sum of squares of residuals : 34.7341 +rel. change during last iteration : -3.36116e-09 + +degrees of freedom (FIT_NDF) : 2 +rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 4.16738 +variance of residuals (reduced chisquare) = WSSR/ndf : 17.367 + +Final set of parameters Asymptotic Standard Error +======================= ========================== +A = 0.587626 +/- 0.04417 (7.517%) +B = -26.8117 +/- 2.112 (7.877%) + +correlation matrix of the fit parameters: + A B +A 1.000 +B 0.163 1.000 + + +******************************************************************************* +Wed Mar 25 17:14:34 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 4 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +iter chisq delta/lim lambda A B + 0 3.9682614810e+03 0.00e+00 3.38e+01 1.000000e+00 1.000000e+00 + 5 3.4734096263e+01 -3.36e-04 3.38e-04 5.876258e-01 -2.681171e+01 + +After 5 iterations the fit converged. +final sum of squares of residuals : 34.7341 +rel. change during last iteration : -3.36116e-09 + +degrees of freedom (FIT_NDF) : 2 +rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 4.16738 +variance of residuals (reduced chisquare) = WSSR/ndf : 17.367 + +Final set of parameters Asymptotic Standard Error +======================= ========================== +A = 0.587626 +/- 0.04417 (7.517%) +B = -26.8117 +/- 2.112 (7.877%) + +correlation matrix of the fit parameters: + A B +A 1.000 +B 0.163 1.000 + + +******************************************************************************* +Wed Mar 25 18:00:20 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 5 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +iter chisq delta/lim lambda A B + 0 4.3038838810e+03 0.00e+00 3.03e+01 1.000000e+00 1.000000e+00 + 5 7.7126310821e+01 -2.27e-05 3.03e-04 5.892187e-01 -2.534379e+01 + +After 5 iterations the fit converged. +final sum of squares of residuals : 77.1263 +rel. change during last iteration : -2.27353e-10 + +degrees of freedom (FIT_NDF) : 3 +rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 5.07038 +variance of residuals (reduced chisquare) = WSSR/ndf : 25.7088 + +Final set of parameters Asymptotic Standard Error +======================= ========================== +A = 0.589219 +/- 0.05373 (9.119%) +B = -25.3438 +/- 2.301 (9.08%) + +correlation matrix of the fit parameters: + A B +A 1.000 +B 0.171 1.000 + + +******************************************************************************* +Wed Mar 25 18:00:37 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 4 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +iter chisq delta/lim lambda A B + 0 3.9682614810e+03 0.00e+00 3.38e+01 1.000000e+00 1.000000e+00 + 5 3.4734096263e+01 -3.36e-04 3.38e-04 5.876258e-01 -2.681171e+01 + +After 5 iterations the fit converged. +final sum of squares of residuals : 34.7341 +rel. change during last iteration : -3.36116e-09 + +degrees of freedom (FIT_NDF) : 2 +rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 4.16738 +variance of residuals (reduced chisquare) = WSSR/ndf : 17.367 + +Final set of parameters Asymptotic Standard Error +======================= ========================== +A = 0.587626 +/- 0.04417 (7.517%) +B = -26.8117 +/- 2.112 (7.877%) + +correlation matrix of the fit parameters: + A B +A 1.000 +B 0.163 1.000 + + +******************************************************************************* +Wed Mar 25 18:00:50 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 5 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +iter chisq delta/lim lambda A B + 0 4.3038838810e+03 0.00e+00 3.03e+01 1.000000e+00 1.000000e+00 + 5 7.7126310821e+01 -2.27e-05 3.03e-04 5.892187e-01 -2.534379e+01 + +After 5 iterations the fit converged. +final sum of squares of residuals : 77.1263 +rel. change during last iteration : -2.27353e-10 + +degrees of freedom (FIT_NDF) : 3 +rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 5.07038 +variance of residuals (reduced chisquare) = WSSR/ndf : 25.7088 + +Final set of parameters Asymptotic Standard Error +======================= ========================== +A = 0.589219 +/- 0.05373 (9.119%) +B = -25.3438 +/- 2.301 (9.08%) + +correlation matrix of the fit parameters: + A B +A 1.000 +B 0.171 1.000 + + +******************************************************************************* +Wed Mar 25 18:01:05 2026 + + +FIT: data read from 'first_test.txt' + format = z + #datapoints = 5 + residuals are weighted equally (unit weight) + +function used for fitting: A*x+B +fitted parameters initialized with current variable values + +iter chisq delta/lim lambda A B + 0 4.3038838810e+03 0.00e+00 3.03e+01 1.000000e+00 1.000000e+00 + 5 7.7126310821e+01 -2.27e-05 3.03e-04 5.892187e-01 -2.534379e+01 + +After 5 iterations the fit converged. +final sum of squares of residuals : 77.1263 +rel. change during last iteration : -2.27353e-10 + +degrees of freedom (FIT_NDF) : 3 +rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 5.07038 +variance of residuals (reduced chisquare) = WSSR/ndf : 25.7088 + +Final set of parameters Asymptotic Standard Error +======================= ========================== +A = 0.589219 +/- 0.05373 (9.119%) +B = -25.3438 +/- 2.301 (9.08%) + +correlation matrix of the fit parameters: + A B +A 1.000 +B 0.171 1.000 diff --git a/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/gnuplotter_first b/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/gnuplotter_first new file mode 100644 index 0000000..9f9014f --- /dev/null +++ b/anasen_analysis_vignesh/scratch/25Mar26_17F_alpha+gaus/gnuplotter_first @@ -0,0 +1,7 @@ +set term qt enhanced +set key top left +A=1; +B=1; +fit A*x+B 'first_test.txt' via A,B +plot 'first_test.txt' w p, A*x+B w l title 'fit' +pause mouse close diff --git a/anasen_analysis_vignesh/scratch/Alternate_PC_wire_interpolation_test.ods b/anasen_analysis_vignesh/scratch/Alternate_PC_wire_interpolation_test.ods new file mode 100644 index 0000000..fb81561 Binary files /dev/null and b/anasen_analysis_vignesh/scratch/Alternate_PC_wire_interpolation_test.ods differ diff --git a/anasen_analysis_vignesh/scratch/flip_anode.h b/anasen_analysis_vignesh/scratch/flip_anode.h new file mode 100644 index 0000000..e69de29 diff --git a/anasen_analysis_vignesh/scratch/flip_cathode.h b/anasen_analysis_vignesh/scratch/flip_cathode.h new file mode 100644 index 0000000..8b13789 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/flip_cathode.h @@ -0,0 +1 @@ + diff --git a/anasen_analysis_vignesh/scratch/flip_offset_scans/scan_offset.C b/anasen_analysis_vignesh/scratch/flip_offset_scans/scan_offset.C new file mode 100644 index 0000000..bfb737a --- /dev/null +++ b/anasen_analysis_vignesh/scratch/flip_offset_scans/scan_offset.C @@ -0,0 +1,38 @@ +int quit=0; +void handler(int){quit=1;} + +void scan_offset(){ + signal(SIGINT,handler); + TCanvas c("c1","c1",0,0,1600,800); + c.Divide(2,1); + for(int i=0; i<=23; i++) { + auto c1=c.cd(1); + c1->SetGrid(1,1); + TFile *f = new TFile(Form("results_run12_anodeoffset%d.root",i)); + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + TH2F *h2 = (TH2F*)(f->Get("pcz_vs_sx3pczguess")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h2) continue; + h2->SetTitle(Form("case%d",i)); + h2->Draw("colz"); + c1->Modified(); + c1->Update(); + + auto c2=c.cd(2); + c2->SetGrid(1,1); + + TH2F *h3 = (TH2F*)(f->Get("sx3phi_vs_pcphi1")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h3) continue; + h3->SetTitle(Form("case%d",i)); + h3->Draw("colz"); + c2->Modified(); + c2->Update(); + + while(gPad->WaitPrimitive()); + + f->Close(); + if(i==23) i=-1; + if(quit) break; + } +} diff --git a/anasen_analysis_vignesh/scratch/flipscan_anode.sh b/anasen_analysis_vignesh/scratch/flipscan_anode.sh new file mode 100644 index 0000000..5e86da8 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/flipscan_anode.sh @@ -0,0 +1,11 @@ +declare -i i=0 +while [[ $i -lt 24 ]]; do + cd .. + export flipa=$i + bash run_sx3.sh + cp results_run12.root results_run12_noflip_anodeoffset$i.root + #cp results_run21.root results_run21_anodeoffset$i.root + cd - + i=i+1 +done +unset flipa diff --git a/anasen_analysis_vignesh/scratch/flipscan_cathode.sh b/anasen_analysis_vignesh/scratch/flipscan_cathode.sh new file mode 100644 index 0000000..d0a90bf --- /dev/null +++ b/anasen_analysis_vignesh/scratch/flipscan_cathode.sh @@ -0,0 +1,11 @@ +declare -i i=0 +while [[ $i -lt 24 ]]; do + cd .. + export flipc=$i + bash run_sx3.sh + cp results_run12.root results_run12_noflip_cathodeoffset$i.root + #cp results_run21.root results_run21_noflip_cathodeoffset$i.root + cd - + i=i+1 +done +unset flipc diff --git a/anasen_analysis_vignesh/scratch/lise.dat b/anasen_analysis_vignesh/scratch/lise.dat new file mode 100644 index 0000000..895e7d5 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/lise.dat @@ -0,0 +1,16 @@ +#ein 1cm-eloss 3cm-eloss +6 0.1446 0.4458 +5.5 0.1579 0.485 +5. 0.1657 0.5149 +4.5 0.1829 0.565 +4. 0.1976 0.617 +3.5 0.2184 0.6878 +3. 0.2441 0.780 +2.5 0.2774 0.911 +2. 0.3231 1.086 +1.5 0.3818 1.19 +1. 0.4242 0.9915 +0.5 0.3439 0.5 +0.2 0.1934 0.2 +0.1 0.1 0.1 + diff --git a/anasen_analysis_vignesh/scratch/noflip_offset_scans/scan_offset.C b/anasen_analysis_vignesh/scratch/noflip_offset_scans/scan_offset.C new file mode 100644 index 0000000..7437a71 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/noflip_offset_scans/scan_offset.C @@ -0,0 +1,22 @@ +int quit=0; +void handler(int){quit=1;} + +void scan_offset(){ + signal(SIGINT,handler); + for(int i=0; i<=23; i++) { + TFile *f = new TFile(Form("results_run12_noflip_anodeoffset%d.root",i)); + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + TH2F *h2 = (TH2F*)(f->Get("pcz_vs_sx3z")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h2) continue; + h2->SetTitle(Form("case%d",i)); + h2->Draw("colz"); + gPad->Modified(); + gPad->Update(); + while(gPad->WaitPrimitive()); + + f->Close(); + if(i==23) i=0; + if(quit) break; + } +} diff --git a/anasen_analysis_vignesh/scratch/phiscan.sh b/anasen_analysis_vignesh/scratch/phiscan.sh new file mode 100644 index 0000000..7e0a22e --- /dev/null +++ b/anasen_analysis_vignesh/scratch/phiscan.sh @@ -0,0 +1,11 @@ +declare -i i=-7 +while [[ $i -lt 3 ]]; do + echo "offset_c1 = -4*k +"$i"*k - TMath::TwoPi()/48;" > testing.h + cd .. + bash run_sx3.sh + j=$(echo $i+3 | bc) + cp results_run12.root results_run12case$j.root + cd - + i=i+1 +done +echo "" > testing.h diff --git a/anasen_analysis_vignesh/scratch/scan_phisearch.C b/anasen_analysis_vignesh/scratch/scan_phisearch.C new file mode 100644 index 0000000..0003c49 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/scan_phisearch.C @@ -0,0 +1,20 @@ +{ + for(int i=-4; i<=5; i++) { + TFile *f = new TFile(Form("../results_run12case%d.root",i)); + TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); +// TH2F *h2 = (TH2F*)(f->Get("pcz_vs_sx3pczguess")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + h2->SetTitle(Form("case%d",i)); + h2->Draw("colz"); + gPad->Modified(); + gPad->Update(); + while(gPad->WaitPrimitive()); + + h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ3")); + h2->Draw("colz"); + gPad->Modified(); + gPad->Update(); + while(gPad->WaitPrimitive()); + f->Close(); + } +} diff --git a/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/scan_offset.C b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/scan_offset.C new file mode 100644 index 0000000..ebf6e22 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/scan_offset.C @@ -0,0 +1,81 @@ +#include "testmodel.h" + +int quit=0; +void handler(int){quit=1;} + +int colors[] = {kSpring+3, kRed, kGreen+3, kBlue+3, kViolet, kOrange, kSpring-7, kAzure-5}; +void scan_offset(){ + signal(SIGINT,handler); + TCanvas c("c1","c1",0,0,1600,800); + c.Divide(2,1); + + TF1 f1("model",model,-200,200,2); + f1.SetNpx(10000); + std::vector pars = {0.0,1.}; + f1.SetParameters(pars.data()); + f1.SetLineColor(kGreen+2); + f1.SetLineStyle(kLine); + + + + + TFile* f=NULL; + std::vector files; + int ctr=0; + for(int i=12; i<=21; i++) { + auto c1=c.cd(1); + c1->SetGrid(1,1); + f = new TFile(Form("../../results_run%d.root",i)); + + if(i==12) { + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + TH2F *h23 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int_A1C2")); + h23->SetLineColorAlpha(kOrange,0.75); + h23->Draw("box SAME"); + + } else { + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + //TH2F *h2 = (TH2F*)(f->Get("pcz_vs_sx3pczguess_A1C2_strip12")); + TH2F *h2 = (TH2F*)(f->Get("pcz_vs_sx3pczguess_A1C2")); + //TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h2) continue; + h2->SetTitle(Form("case%d",i)); + //h2->Draw("colz same"); + h2->SetLineColorAlpha(colors[ctr],0.75); + h2->Draw("box same"); + f1.Draw("same"); + } + TF1 eqline("x","x",-200,200); + eqline.Draw("SAME"); + c1->Modified(); + c1->Update(); + ctr+=1; + + + auto c2=c.cd(2); + c2->SetGrid(1,1); + + TH2F *h3 = (TH2F*)(f->Get("sx3phi_vs_pcphi1")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h3) continue; + h3->SetTitle(Form("case%d",i)); + h3->Draw("colz"); + eqline.Draw("SAME"); + c2->Modified(); + c2->Update(); + + while(gPad->WaitPrimitive()); + + files.emplace_back(f); + if(i==21) { + i=11; + c.Clear(); + c.Divide(2,1); + ctr=0; + } + if(quit) break; + } + for(auto file : files) { + file->Close(); + } +} diff --git a/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/scan_offset_fix.C b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/scan_offset_fix.C new file mode 100644 index 0000000..e94faad --- /dev/null +++ b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/scan_offset_fix.C @@ -0,0 +1,81 @@ +#include "testmodel.h" + +int quit=0; +void handler(int){quit=1;} + +int colors[] = {kSpring+3, kRed, kGreen+3, kBlue+3, kViolet, kOrange, kSpring-7, kAzure-5}; +void scan_offset_fix(){ + signal(SIGINT,handler); + TCanvas c("c1","c1",0,0,1600,800); + c.Divide(2,1); + + TF1 f1("model",model,-200,200,2); + f1.SetNpx(10000); + std::vector pars = {0.0,1.}; + f1.SetParameters(pars.data()); + f1.SetLineColor(kGreen+2); + f1.SetLineStyle(kLine); + + + + + TFile* f=NULL; + std::vector files; + int ctr=0; + for(int i=12; i<=21; i++) { + auto c1=c.cd(1); + c1->SetGrid(1,1); + f = new TFile(Form("../../results_run%d.root",i)); + + if(i==12) { + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + TH2F *h23 = (TH2F*)(f->Get("pczfix_vs_qqqpczguess_A1C2")); + h23->SetLineColorAlpha(kOrange,0.75); + h23->Draw("SAME"); + + } else { + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + //TH2F *h2 = (TH2F*)(f->Get("pcz_vs_sx3pczguess_A1C2_strip12")); + TH2F *h2 = (TH2F*)(f->Get("pczfix_vs_sx3pczguess_A1C2")); + //TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h2) continue; + h2->SetTitle(Form("case%d",i)); + //h2->Draw("colz same"); + h2->SetLineColorAlpha(colors[ctr],0.75); + h2->Draw("box same"); + //f1.Draw("same"); + } + TF1 eqline("x","x",-200,200); + eqline.Draw("SAME"); + c1->Modified(); + c1->Update(); + ctr+=1; + + + auto c2=c.cd(2); + c2->SetGrid(1,1); + + TH2F *h3 = (TH2F*)(f->Get("sx3phi_vs_pcphi1")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h3) continue; + h3->SetTitle(Form("case%d",i)); + h3->Draw("colz"); + eqline.Draw("SAME"); + c2->Modified(); + c2->Update(); + + while(gPad->WaitPrimitive()); + + files.emplace_back(f); + if(i==21) { + i=11; + c.Clear(); + c.Divide(2,1); + ctr=0; + } + if(quit) break; + } + for(auto file : files) { + file->Close(); + } +} diff --git a/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/stitch.C b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/stitch.C new file mode 100644 index 0000000..4fbaa02 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/stitch.C @@ -0,0 +1,5 @@ +{ + + + +} diff --git a/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/testmodel.h b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/testmodel.h new file mode 100644 index 0000000..458d808 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/sx3z_vs_phiz/testmodel.h @@ -0,0 +1,43 @@ +#include +double model(double* x, double* p) { + double result = x[0]; + double factor = 29.0; + double slope = 0.7; + if(TMath::Abs(x[0]) < 16.2) result=x[0]*slope; + else if(TMath::Abs(x[0]) < 49.8 ) result=x[0]*slope+TMath::Sign(1.0,x[0])*factor; + else if(TMath::Abs(x[0]) < 85.2 ) result=x[0]*slope+TMath::Sign(1.0,x[0])*factor*2; + else result=x[0]*slope+TMath::Sign(1.0,x[0])*factor*2; + return result; +} + +double model_invert(double *y, double *q) { + double result=y[0]; + double slope = 0.7; + double factor = 40.0; + if(TMath::Abs(y[0]) < 16.2/slope) result = y[0]/slope; + else if(TMath::Abs(y[0]) < 49.8/slope ) result=y[0]/slope-TMath::Sign(1.0,y[0])*factor; + else if(TMath::Abs(y[0]) < 85.2/slope ) result=y[0]/slope-TMath::Sign(1.0,y[0])*factor*2; + else result=y[0]/slope-TMath::Sign(1.0,y[0])*factor*2; + return result; + +} + +/*void testmodel() { + TF1 eqline("x","x",-200,200); + eqline.Draw(""); + eqline.SetLineStyle(kDashed); + + //TF1 f1("model",model,-200,200,2); + TF1 f1("model_inv",model_invert,-200,200,2); + eqline.SetNpx(10000); + f1.SetNpx(10000); + std::vector pars = {0.0,1.}; + f1.SetParameters(pars.data()); + f1.SetLineColor(kGreen+2); + f1.SetLineStyle(kLine); + f1.Draw("L SAME"); + + gPad->Modified(); gPad->Update(); + while(gPad->WaitPrimitive()); + +}*/ diff --git a/anasen_analysis_vignesh/scratch/test.dat b/anasen_analysis_vignesh/scratch/test.dat new file mode 100644 index 0000000..277dd84 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/test.dat @@ -0,0 +1,7 @@ +1.00490190125271 1.81526549142349 +2.1078430941584 1.4359987348238 +3.02287578753202 1.14680783291655 +3.87254900280751 0.971396957989193 +4.67320260950942 0.852876096551793 +5.44117647716228 0.819690255349321 +6.02124184528305 0.800726917519336 diff --git a/anasen_analysis_vignesh/scratch/testing.h b/anasen_analysis_vignesh/scratch/testing.h new file mode 100644 index 0000000..8b13789 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/testing.h @@ -0,0 +1 @@ + diff --git a/anasen_analysis_vignesh/scratch/testme.dat b/anasen_analysis_vignesh/scratch/testme.dat new file mode 100644 index 0000000..c43f35e --- /dev/null +++ b/anasen_analysis_vignesh/scratch/testme.dat @@ -0,0 +1,29 @@ +{ +//========= Macro generated from object: Graph/Graph +//========= by ROOT version6.36.04 + + std::vector graph_x_vect0{ 1.00490190125271, 2.107843094158404, 3.022875787532016, 3.872549002807514, 4.673202609509424, 5.441176477162277, 6.02124184528305 }; + std::vector graph_y_vect1{ 18152.65491423486, 14359.98734823804, 11468.07832916546, 9713.969579891931, 8528.760965517926, 8196.902553493204, 8007.269175193363 }; + TGraph *graph = new TGraph(7, graph_x_vect0.data(), graph_y_vect1.data()); + graph->SetName("Graph"); + graph->SetTitle("Graph"); + graph->SetFillStyle(1000); + + TH1F *Graph_histogram1 = new TH1F("Graph_histogram1", "Graph", 100, 0.4542482982760897, 6.473856231112497); + Graph_histogram1->SetMinimum(7324.589013313936); + Graph_histogram1->SetMaximum(19499.05190016373); + Graph_histogram1->SetDirectory(nullptr); + Graph_histogram1->SetStats(0); + Graph_histogram1->SetLineColor(TColor::GetColor("#000099")); + Graph_histogram1->GetXaxis()->SetLabelFont(42); + Graph_histogram1->GetXaxis()->SetTitleOffset(1); + Graph_histogram1->GetXaxis()->SetTitleFont(42); + Graph_histogram1->GetYaxis()->SetLabelFont(42); + Graph_histogram1->GetYaxis()->SetTitleFont(42); + Graph_histogram1->GetZaxis()->SetLabelFont(42); + Graph_histogram1->GetZaxis()->SetTitleOffset(1); + Graph_histogram1->GetZaxis()->SetTitleFont(42); + graph->SetHistogram(Graph_histogram1); + + graph->Draw(); +} diff --git a/anasen_analysis_vignesh/scratch/wire#_vs_sx3zphi/scan_offset.C b/anasen_analysis_vignesh/scratch/wire#_vs_sx3zphi/scan_offset.C new file mode 100644 index 0000000..5973732 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/wire#_vs_sx3zphi/scan_offset.C @@ -0,0 +1,38 @@ +int quit=0; +void handler(int){quit=1;} + +void scan_offset(){ + signal(SIGINT,handler); + TCanvas c("c1","c1",0,0,1600,800); + c.Divide(1,1); + for(int i=0; i<=23; i++) { + auto c1=c.cd(1); + c1->SetGrid(1,1); + TFile *f = new TFile(Form("../../results_run21.root")); + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + TH2F *h2 = (TH2F*)(f->Get(std::string("sx3_z_phi2_awire"+std::to_string(i)).c_str())); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h2) continue; + h2->SetTitle(Form("anode_wire%d",i)); + h2->Draw("colz"); + c1->Modified(); + c1->Update(); + +/* auto c2=c.cd(2); + c2->SetGrid(1,1); + + TH2F *h3 = (TH2F*)(f->Get("sx3phi_vs_pcphi1")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h3) continue; + h3->SetTitle(Form("case%d",i)); + h3->Draw("colz"); + c2->Modified(); + c2->Update();*/ + + while(gPad->WaitPrimitive()); + + f->Close(); + if(i==23) i=0; + if(quit) break; + } +} diff --git a/anasen_analysis_vignesh/scratch/wire#_vs_sx3zphi/scan_offset_c.C b/anasen_analysis_vignesh/scratch/wire#_vs_sx3zphi/scan_offset_c.C new file mode 100644 index 0000000..81e3bf4 --- /dev/null +++ b/anasen_analysis_vignesh/scratch/wire#_vs_sx3zphi/scan_offset_c.C @@ -0,0 +1,38 @@ +int quit=0; +void handler(int){quit=1;} + +void scan_offset_c(){ + signal(SIGINT,handler); + TCanvas c("c1","c1",0,0,1600,800); + c.Divide(1,1); + for(int i=0; i<=23; i++) { + auto c1=c.cd(1); + c1->SetGrid(1,1); + TFile *f = new TFile(Form("../../results_run21.root")); + //TH2F *h2 = (TH2F*)(f->Get("phicut/pczguess_vs_pc_int")); + TH2F *h2 = (TH2F*)(f->Get(std::string("sx3_z_phi2_cwire"+std::to_string(i)).c_str())); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h2) continue; + h2->SetTitle(Form("cathode_wire%d",i)); + h2->Draw("colz"); + c1->Modified(); + c1->Update(); + +/* auto c2=c.cd(2); + c2->SetGrid(1,1); + + TH2F *h3 = (TH2F*)(f->Get("sx3phi_vs_pcphi1")); +// TH2F *h2 = (TH2F*)(f->Get("hPCQQQ/PC_XY_Projection_QQQ2")); + if(!h3) continue; + h3->SetTitle(Form("case%d",i)); + h3->Draw("colz"); + c2->Modified(); + c2->Update();*/ + + while(gPad->WaitPrimitive()); + + f->Close(); + if(i==23) i=0; + if(quit) break; + } +} diff --git a/anasen_analysis_vignesh/script.C b/anasen_analysis_vignesh/script.C new file mode 100644 index 0000000..8ffb031 --- /dev/null +++ b/anasen_analysis_vignesh/script.C @@ -0,0 +1,292 @@ +// #include "/home/splitpole/FSUDAQ_Qt6/Aux/fsuReader.h" +// #include "/home/splitpole/FSUDAQ_Qt6/Aux/fsutsReader.h" +#include +#include +#include +#include +#include +#include +#include + +#include "mapping.h" + +#include "Armory/ClassAnasen.h" + +class PulserChecker { +public: + PulserChecker(int sn) : SN(sn){ + t0 = 0; + t1 = 0; + dt = 0; + tStart = -1; + has1stData = false; + n = 0; + mean = 0; + m2 = 0; + } + + void addTime(unsigned long long time){ + t0 = t1; + t1 = time; + if( has1stData ) { + dt = t1/1e6 - t0/1e6; + int mod = 1; + if( dt >= 2* mean && mean > 0 ){ + mod = std::round(dt/mean); + } + if( mod > 1 ) return; + double new_dt = dt/mod; + + n ++; + double delta = new_dt - mean; + mean += delta / n; + + double delta2 = new_dt - mean; + m2 += delta * delta2; + //if( mod > 1 ) printf("%6d | %llu, %llu (dt %.6f, m : %d) | %.6f\n", SN, t1, t0, dt, mod, new_dt); + }else{ + tStart = time; + has1stData = true; + } + // printf("%6d | %13llu, %13llu | %.6f | %13llu\n", SN, t1, t0, dt, tStart); + } + + unsigned long long getTime0() const {return tStart;} + int getSN() const {return SN;} + double getDT() const {return has1stData ? dt : TMath::QuietNaN() ;} + double getMean() const {return mean;} + double getSTD() const { return n < 2 ? 0.0 :sqrt(m2 / (n - 1)); } + + void Print() { printf("%6d (%2d) | %16llu| n : %6d, mean : %10.6f msec, sd : %10.6f msec\n", + SN, SN & 0x1F, tStart, n, getMean(), getSTD());} + +private: + const int SN; + unsigned long long tStart, t0, t1; + double dt; + bool has1stData; + + int n; + double mean; + double m2; + +}; + +void script(TString fileName = "", int maxEvent = -1){ + + /* + //+++++++++++++++++++++++++++++++++++++++++++ + FSUReader * reader = new FSUReader("pulsertest_013_15528_QDC_16_000.fsu", 100); + + reader->ScanNumBlock(1, 1); + reader->PrintHit(10); + + // for( int i = 0; i < 24 ; i++){ + // printf("#################### agg : %d \n", i); + + // reader->ReadNextBlock(false, 0, 1); + + // reader->GetData()->PrintAllData(); + + // } + + + // TGraph * graph = new TGraph(); + // int count = 0; + // unsigned long long tree0 = 0; + // unsigned long numHit = reader->GetHitCount(); + // for( unsigned long i = 0; i < numHit; i++){ + // //printf("-------------%6lu \n\033[A\r", i); + // unsigned long long t1 = reader->GetHit(i).timestamp; + // unsigned short ch = reader->GetHit(i).ch; + // unsigned short ee = reader->GetHit(i).energy; + // //printf("%6lu | %2u, %6u, %16llu\n", i, ch, ee, t1); + // count ++; + // graph->SetPoint(i, i, t1/1e9); + // } + // graph->Draw("APL"); + + // for( int i = 40; i < 60; i++){ + // reader->GetHit(i).Print(); + // } + */ + + /* + //+++++++++++++++++++++++++++++++++++++++++++ + + TFile * file0 = new TFile("test_002_1000_noTrace.root"); + TFile * f1 = new TFile("test_002_1000.root"); + + TTree * tree0 = (TTree*) file0->Get("tree"); + TTree * t1 = (TTree*) f1->Get("tree"); + + unsigned int m0, m1; + unsigned short ch0[100], ch1[100]; + unsigned long long ts0[100], ts1[100]; + + + tree0->SetBranchAddress("multi", &m0); + tree0->SetBranchAddress("ch", ch0); + tree0->SetBranchAddress("e_t", ts0); + + t1->SetBranchAddress("multi", &m1); + t1->SetBranchAddress("ch", ch1); + t1->SetBranchAddress("e_t", ts1); + + unsigned long long nEntries0 = tree0->GetEntries(); + unsigned long long nEntries1 = t1->GetEntries(); + + for( unsigned long long ev = 0; ev < nEntries0; ev++){ + tree0->GetEntry(ev); + t1->GetEntry(ev); + + + if( ch0[0] != ch1[0] || ts0[0] != ts1[0] ) { + printf("======================= %llu \n", ev); + printf("ch : %u %u\n", ch0[0], ch1[0]); + printf("ts : %llu %llu\n", ts0[0], ts1[0]); + } + } + + file0->Close(); + f1->Close(); + */ + /* + //+++++++++++++++++++++++++++++++++++++++++++ + printf("######### file : %s \n", fileName.Data()); + TFile * file0 = new TFile(fileName); + + TTree * tree0 = (TTree*) file0->Get("tree"); + + const int MAX_MULTI = 1000; + unsigned long long evID = 0; + unsigned int multi = 0; + unsigned short sn[MAX_MULTI] = {0}; + unsigned short ch[MAX_MULTI] = {0}; + unsigned short e[MAX_MULTI] = {0}; +// unsigned short e2[MAX_MULTI] = {0}; + unsigned long long e_t[MAX_MULTI] = {0}; +// unsigned short e_f[MAX_MULTI] = {0}; + + tree0->SetBranchAddress("evID", &evID); + tree0->SetBranchAddress("multi", &multi); + tree0->SetBranchAddress("sn", sn); + tree0->SetBranchAddress("ch", ch); + tree0->SetBranchAddress("e", e); + tree0->SetBranchAddress("e_t", e_t); + + unsigned long long nEntries = tree0->GetEntries(); + + const std::map board = { + {0, 17122}, + {1, 17123}, + {2, 22320}, + {3, 22130}, + {4, 22129}, + {5, 15529}, + {6, 15528}, + {7, 379}, + {8, 409}, + {9, 405}, + }; + const int nBd = board.size(); + + PulserChecker * stat[9]; + for( int i = 0; i < nBd; i++){ stat[i] = new PulserChecker(board.at(i)); } + + printf("Number of Entries : %llu\n", nEntries); + + unsigned long long evEnd = nEntries; + if( maxEvent >= 0 ) evEnd = maxEvent; + + for( unsigned long long ev = 0; ev < evEnd; ev++){ + tree0->GetEntry(ev); + + // printf("sn : %5d | %14llu \n", sn[0], e_t[0]); + + for( int i = 0; i< nBd; i++){ + for( unsigned int j = 0; j < multi; j++){ + if( sn[j] == stat[i]->getSN() ) { + stat[i]->addTime(e_t[j]); + printf(" sn : %5d | %16llu \n", sn[j], e_t[j]); + break; + } + } + } + + if( ev > 1){ + unsigned long long ts1 = e_t[0]; + tree0->GetEntry(ev-1); + unsigned long long ts0 = e_t[0]; + + if( ts1 <= ts0 )printf("--------------- ev : %llu\n", ev); + } + } + file0->Close(); + + printf("=========================\n"); + + for( int i = 0; i< nBd; i++){ stat[i]->Print(); } + + unsigned long long time0 = stat[0]->getTime0(); + for( int i = 1; i< nBd; i++){ + if( stat[i]->getTime0() < time0 ) time0 = stat[i]->getTime0(); + } + + printf("=========================\n"); + printf(" S/N time Offset ns \n"); + for( int i = 0; i< nBd; i++){ + printf(" %5d | %16llu \n", stat[i]->getSN(), stat[i]->getTime0() - time0); + } + */ + //+++++++++++++++++++++++++++++++++++++++++++ + // TCanvas * c1 = new TCanvas(); + // ANASEN * kaka = new ANASEN(); + // kaka->DrawAnasen(); + + TCanvas * c2 = new TCanvas("c2", "ANASEN Simulation", 800, 800); + c2->cd(); + + + ANASEN * haha = new ANASEN(); + + haha->SetUncertainties(0, 0, 0, 0); + + PW * pw = haha->GetPW(); + SX3 * sx3 = haha->GetSX3(); + + // haha->DrawAnasen(0, 1, 0, 1, -1, false); + + gRandom->SetSeed(0); + + int xRan = gRandom->Integer(20) - 10; + int yRan = gRandom->Integer(20) - 10; + int zRan = gRandom->Integer(20) - 10; + int pRan = gRandom->Integer(60) -120; // phi deg + + int tRan = 0 ; + do{ + tRan = gRandom->Integer(100) + 40 ; // theta deg + }while( 75 < tRan && tRan < 105); + + TVector3 pos (xRan, yRan, zRan); + TVector3 dir (1, 0, 0); + + dir.SetPhi( pRan * TMath::DegToRad()); + dir.SetTheta( tRan * TMath::DegToRad()); + + pos.Print(); + dir.Print(); + + haha->DrawTrack(pos, dir, true); + + pw->FindWireID(pos, dir, true); + sx3->FindSX3Pos(pos, dir, true); + + + // haha->CalTrack(sx3.hitPos, wireID.first, wireID.second, true); + + //haha->DrawDeducedTrack(sx3.hitPos, wireID.first, wireID.second); + + +} diff --git a/anasen_analysis_vignesh/slope_intercept_cathode.dat b/anasen_analysis_vignesh/slope_intercept_cathode.dat new file mode 100644 index 0000000..1e3c6d2 --- /dev/null +++ b/anasen_analysis_vignesh/slope_intercept_cathode.dat @@ -0,0 +1,23 @@ +Histogram Number Slope Intercept +24 1 -2.89219e-10 +25 0.942098 -0.105169 +26 0.980862 -0.732032 +27 0.982975 -2.22704 +28 0.978815 -1.51477 +29 0.965245 -2.19515 +30 0.945384 -0.892599 +31 0.977408 -0.908592 +32 0.919546 3.25464 +33 0.972194 2.44956 +34 0.92852 5.44745 +35 0.947098 1.40531 +36 0.875491 -1.13145 +37 1.95496 -1735.58 +38 0.970862 2.86019 +40 0.91793 -3.80615 +41 0.913897 -2.12964 +42 0.954014 -0.760604 +43 0.993616 -1.40278 +45 0.926169 -21.2016 +46 1.00577 -2.14281 +47 0.943312 -1.26464 diff --git a/anasen_analysis_vignesh/slope_intercept_results.dat b/anasen_analysis_vignesh/slope_intercept_results.dat new file mode 100644 index 0000000..a29898b --- /dev/null +++ b/anasen_analysis_vignesh/slope_intercept_results.dat @@ -0,0 +1,49 @@ +#Histogram Number Slope Intercept +0 0.931015 -1.35431 +1 1 -1.87356e-10 +2 0.964185 1.49989 +3 0.92638 -1.30621 +4 0.905569 1.00834 +5 0.901182 0.470903 +6 0.853932 3.32687 +7 0.942785 1.08887 +8 0.878904 -0.0107433 +9 0.922662 -2.32259 +10 0.903343 8.38332 +11 0.914227 6.56108 +12 0.961008 23.0982 +13 0.920976 5.22104 +14 0.936584 31.5073 +15 0.959044 5.43267 +16 0.95263 -0.404053 +17 0.90953 4.82833 +18 0.940277 10.3629 +19 0.86746 -17.8678 +20 1.00683 4.76371 +21 0.968342 -43.9496 +22 0.892882 -32.0742 +23 0.933615 1.10704 +24 1 -2.89219e-10 +25 0.942098 -0.105169 +26 0.980862 -0.732032 +27 0.982975 -2.22704 +28 0.978815 -1.51477 +29 0.965245 -2.19515 +30 0.945384 -0.892599 +31 0.977408 -0.908592 +32 0.919546 3.25464 +33 0.972194 2.44956 +34 0.92852 5.44745 +35 0.947098 1.40531 +36 0.875491 -1.13145 +37 1 0 +38 0.970862 2.86019 +39 1 0 +40 0.91793 -3.80615 +41 0.913897 -2.12964 +42 0.954014 -0.760604 +43 0.993616 -1.40278 +44 1 0 +45 0.926169 -21.2016 +46 1.00577 -2.14281 +47 0.943312 -1.26464 diff --git a/anasen_analysis_vignesh/slope_intercept_results_anode.dat b/anasen_analysis_vignesh/slope_intercept_results_anode.dat new file mode 100644 index 0000000..e01ffa3 --- /dev/null +++ b/anasen_analysis_vignesh/slope_intercept_results_anode.dat @@ -0,0 +1,21 @@ +Histogram Number Slope Intercept +1 1 -1.87356e-10 +2 0.964185 1.49989 +3 0.92638 -1.30621 +4 0.905569 1.00834 +5 0.901182 0.470903 +7 0.942785 1.08887 +8 0.878904 -0.0107433 +10 0.903343 8.38332 +11 0.914227 6.56108 +12 0.961008 23.0982 +13 0.920976 5.22104 +14 0.936584 31.5073 +15 0.959044 5.43267 +16 0.95263 -0.404053 +17 0.90953 4.82833 +18 0.940277 10.3629 +20 1.00683 4.76371 +21 0.968342 -43.9496 +22 0.892882 -32.0742 +23 0.933615 1.10704 diff --git a/anasen_analysis_vignesh/sx3cal/17F/backgains.dat b/anasen_analysis_vignesh/sx3cal/17F/backgains.dat new file mode 100644 index 0000000..da529ce --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/17F/backgains.dat @@ -0,0 +1,55 @@ +1 front 0 back 3 3.68208 +1 front 0 back 0 3.89631 +1 front 1 back 2 4.44599 +1 front 1 back 3 3.81311 +1 front 1 back 0 3.98321 +1 front 2 back 2 4.52103 +1 front 2 back 3 3.68208 +1 front 2 back 0 3.95382 +1 front 3 back 2 4.55951 +1 front 3 back 3 3.68208 +1 front 3 back 0 3.89631 +3 front 1 back 2 3.81311 +3 front 1 back 1 3.92485 +3 front 1 back 3 4.13701 +3 front 1 back 0 4.26886 +3 front 2 back 2 3.86817 +3 front 2 back 1 4.04334 +3 front 2 back 3 3.98321 +3 front 2 back 0 4.23512 +3 front 3 back 2 3.92485 +3 front 3 back 1 3.92485 +3 front 3 back 3 3.95382 +3 front 3 back 0 4.13701 +7 front 0 back 2 3.65694 +7 front 0 back 1 3.53625 +7 front 0 back 3 4.23512 +7 front 0 back 0 3.60769 +7 front 1 back 2 3.65694 +7 front 1 back 1 3.53625 +7 front 1 back 3 4.23512 +7 front 1 back 0 3.58356 +7 front 2 back 2 3.68208 +7 front 2 back 1 3.55975 +7 front 2 back 3 4.13701 +7 front 2 back 0 3.60769 +7 front 3 back 2 3.68208 +7 front 3 back 1 3.53625 +7 front 3 back 3 4.23512 +7 front 3 back 0 3.58356 +9 front 0 back 2 3.68208 +9 front 0 back 1 3.53625 +9 front 0 back 3 3.51306 +9 front 0 back 0 3.42327 +9 front 1 back 2 3.70756 +9 front 1 back 1 3.49018 +9 front 1 back 3 3.63215 +9 front 1 back 0 3.46759 +9 front 2 back 2 3.70756 +9 front 2 back 1 3.55975 +9 front 2 back 3 3.53625 +9 front 2 back 0 3.44529 +9 front 3 back 2 3.7334 +9 front 3 back 1 3.51306 +9 front 3 back 3 3.53625 +9 front 3 back 0 3.42327 diff --git a/anasen_analysis_vignesh/sx3cal/17F/backgains.dat.unity b/anasen_analysis_vignesh/sx3cal/17F/backgains.dat.unity new file mode 100644 index 0000000..b7b2b5f --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/17F/backgains.dat.unity @@ -0,0 +1,96 @@ +1 0 0 1. +1 1 0 1. +1 2 0 1. +1 3 0 1. +1 0 1 1. +1 1 1 1. +1 2 1 1. +1 3 1 1. +1 0 2 1. +1 1 2 1. +1 2 2 1. +1 3 2 1. +1 0 3 1. +1 1 3 1. +1 2 3 1. +1 3 3 1. +7 0 0 1. +7 1 0 1. +7 2 0 1. +7 3 0 1. +7 0 1 1. +7 1 1 1. +7 2 1 1. +7 3 1 1. +7 0 2 1. +7 1 2 1. +7 2 2 1. +7 3 2 1. +7 0 3 1. +7 1 3 1. +7 2 3 1. +7 3 3 1. +0 0 0 1. +0 1 0 1. +0 2 0 1. +0 3 0 1. +0 0 1 1. +0 1 1 1. +0 2 1 1. +0 3 1 1. +0 0 2 1. +0 1 2 1. +0 2 2 1. +0 3 2 1. +0 0 3 1. +0 1 3 1. +0 2 3 1. +0 3 3 1. +2 0 0 1. +2 1 0 1. +2 2 0 1. +2 3 0 1. +2 0 1 1. +2 1 1 1. +2 2 1 1. +2 3 1 1. +2 0 2 1. +2 1 2 1. +2 2 2 1. +2 3 2 1. +2 0 3 1. +2 1 3 1. +2 2 3 1. +2 3 3 1. +9 0 0 1. +9 1 0 1. +9 2 0 1. +9 3 0 1. +9 0 1 1. +9 1 1 1. +9 2 1 1. +9 3 1 1. +9 0 2 1. +9 1 2 1. +9 2 2 1. +9 3 2 1. +9 0 3 1. +9 1 3 1. +9 2 3 1. +9 3 3 1. +3 0 0 1. +3 1 0 1. +3 2 0 1. +3 3 0 1. +3 0 1 1. +3 1 1 1. +3 2 1 1. +3 3 1 1. +3 0 2 1. +3 1 2 1. +3 2 2 1. +3 3 2 1. +3 0 3 1. +3 1 3 1. +3 2 3 1. +3 3 3 1. diff --git a/anasen_analysis_vignesh/sx3cal/17F/frontgains.dat b/anasen_analysis_vignesh/sx3cal/17F/frontgains.dat new file mode 100644 index 0000000..6cf56c0 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/17F/frontgains.dat @@ -0,0 +1,15 @@ +1 lengthcal front 0 0.302419 60.4839 +1 lengthcal front 1 0.907258 60.4839 +1 lengthcal front 2 -2.11694 60.4839 +1 lengthcal front 3 3.32661 60.4839 +3 lengthcal front 1 -0.302419 60.4839 +3 lengthcal front 2 -3.12146 59.4564 +3 lengthcal front 3 5.3066 62.4306 +7 lengthcal front 0 0.225805 45.1611 +7 lengthcal front 1 1.85157 46.2892 +7 lengthcal front 2 0.936622 46.8311 +7 lengthcal front 3 3.65527 45.6909 +9 lengthcal front 0 2.10806 46.8457 +9 lengthcal front 1 0.694127 46.2751 +9 lengthcal front 2 1.04095 46.2646 +9 lengthcal front 3 1.99048 46.8348 diff --git a/anasen_analysis_vignesh/sx3cal/17F/frontgains.dat.unity b/anasen_analysis_vignesh/sx3cal/17F/frontgains.dat.unity new file mode 100644 index 0000000..a6df93c --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/17F/frontgains.dat.unity @@ -0,0 +1,24 @@ +9 temp temp 0 0. 1. +9 temp temp 1 0. 1. +9 temp temp 2 0. 1. +9 temp temp 3 0. 1. +7 temp temp 0 0. 1. +7 temp temp 1 0. 1. +7 temp temp 2 0. 1. +7 temp temp 3 0. 1. +1 temp temp 0 0. 1. +1 temp temp 1 0. 1. +1 temp temp 2 0. 1. +1 temp temp 3 0. 1. +2 temp temp 0 0. 1. +2 temp temp 1 0. 1. +2 temp temp 2 0. 1. +2 temp temp 3 0. 1. +0 temp temp 0 0. 1. +0 temp temp 1 0. 1. +0 temp temp 2 0. 1. +0 temp temp 3 0. 1. +3 temp temp 0 0. 1. +3 temp temp 1 0. 1. +3 temp temp 2 0. 1. +3 temp temp 3 0. 1. diff --git a/anasen_analysis_vignesh/sx3cal/17F/rightgains.dat b/anasen_analysis_vignesh/sx3cal/17F/rightgains.dat new file mode 100644 index 0000000..e74d0cd --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/17F/rightgains.dat @@ -0,0 +1,16 @@ +1 0 1239.16 0.649287 +1 1 1853.11 1.08968 +1 2 1852.65 1.10279 +1 3 1821.01 0.965101 +3 0 1749.6 1. +3 1 1749.6 1.01204 +3 2 1954.81 1.23687 +3 3 1751.15 0.904329 +9 0 1838.02 1.07361 +9 1 1695.51 0.971866 +9 2 1709.36 0.988575 +9 3 1719.37 0.982937 +7 0 1787.9 1.02266 +7 1 1924.89 1.10649 +7 2 1706.01 1.03175 +7 3 1685.88 0.933633 diff --git a/anasen_analysis_vignesh/sx3cal/17F/rightgains.dat.unity b/anasen_analysis_vignesh/sx3cal/17F/rightgains.dat.unity new file mode 100644 index 0000000..2f7a305 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/17F/rightgains.dat.unity @@ -0,0 +1,24 @@ +9 0 1000 1.0 +9 1 1000 1.0 +9 2 1000 1.0 +9 3 1000 1.0 +7 0 1000 1.0 +7 1 1000 1.0 +7 2 1000 1.0 +7 3 1000 1.0 +2 0 1000 1.0 +2 1 1000 1.0 +2 2 1000 1.0 +2 3 1000 1.0 +0 0 1000 1.0 +0 1 1000 1.0 +0 2 1000 1.0 +0 3 1000 1.0 +1 0 1000 1.0 +1 1 1000 1.0 +1 2 1000 1.0 +1 3 1000 1.0 +3 0 1000 1.0 +3 1 1000 1.0 +3 2 1000 1.0 +3 3 1000 1.0 diff --git a/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat b/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat new file mode 100644 index 0000000..278ae78 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat @@ -0,0 +1,56 @@ +1 front 0 back 2 3.63215 +1 front 0 back 3 3.23711 +1 front 0 back 0 3.44529 +1 front 1 back 2 3.63215 +1 front 1 back 3 3.38008 +1 front 1 back 0 3.46759 +1 front 2 back 2 3.70756 +1 front 2 back 3 3.21767 +1 front 2 back 0 3.46759 +1 front 3 back 2 3.75959 +1 front 3 back 3 3.21767 +1 front 3 back 0 3.44529 +7 front 0 back 2 3.78616 +7 front 0 back 1 3.07016 +7 front 0 back 3 3.68208 +7 front 0 back 0 3.14218 +7 front 1 back 2 3.81311 +7 front 1 back 1 3.12386 +7 front 1 back 3 3.65694 +7 front 1 back 0 3.14218 +7 front 2 back 2 3.84045 +7 front 2 back 1 3.14218 +7 front 2 back 3 3.60769 +7 front 2 back 0 3.14218 +7 front 3 back 2 3.86817 +7 front 3 back 1 3.12386 +7 front 3 back 3 3.68208 +7 front 3 back 0 3.14218 +9 front 0 back 2 3.29688 +9 front 0 back 1 3.12386 +9 front 0 back 3 3.12386 +9 front 0 back 0 3.03537 +9 front 1 back 2 3.29688 +9 front 1 back 1 3.12386 +9 front 1 back 3 3.14218 +9 front 1 back 0 3.05266 +9 front 2 back 2 3.29688 +9 front 2 back 1 3.14218 +9 front 2 back 3 3.12386 +9 front 2 back 0 3.05266 +9 front 3 back 2 3.29688 +9 front 3 back 1 3.12386 +9 front 3 back 3 3.08785 +9 front 3 back 0 3.03537 +3 front 1 back 2 3.31729 +3 front 1 back 1 3.38008 +3 front 1 back 3 3.65694 +3 front 1 back 0 3.53625 +3 front 2 back 2 3.38008 +3 front 2 back 1 3.44529 +3 front 2 back 3 3.46759 +3 front 2 back 0 3.51306 +3 front 3 back 2 3.38008 +3 front 3 back 1 3.33796 +3 front 3 back 3 3.46759 +3 front 3 back 0 3.46759 diff --git a/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat.Apr2026 b/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat.Apr2026 new file mode 100644 index 0000000..b111f4d --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat.Apr2026 @@ -0,0 +1,41 @@ +#1 front 0 back 2 4.03168 +#1 front 1 back 2 4.03168 +#1 front 2 back 2 4.11533 +#1 front 3 back 2 4.17315 +1 front 0 back 2 3.63215 +1 front 0 back 3 3.23711 +1 front 0 back 0 3.44529 +1 front 1 back 2 3.63215 +1 front 1 back 3 3.38008 +1 front 1 back 0 3.46759 +1 front 2 back 2 3.70756 +1 front 2 back 3 3.21767 +1 front 2 back 0 3.46759 +1 front 3 back 2 3.75959 +1 front 3 back 3 3.21767 +1 front 3 back 0 3.44529 +# +7 front 0 back 2 4.26886 +7 front 0 back 1 3.44529 +7 front 1 back 2 4.26886 +7 front 1 back 1 3.44529 +7 front 2 back 2 4.26886 +7 front 2 back 1 3.46759 +7 front 3 back 2 4.26886 +7 front 3 back 1 3.44529 +9 front 0 back 2 3.63215 +9 front 0 back 1 3.42327 +9 front 1 back 2 3.63215 +9 front 1 back 1 3.42327 +9 front 2 back 2 3.65694 +9 front 2 back 1 3.46759 +9 front 3 back 2 3.68208 +9 front 3 back 1 3.42327 +3 front 0 back 2 3. +3 front 0 back 1 3. +3 front 1 back 2 3.65694 +3 front 1 back 1 3.68208 +3 front 2 back 2 3.70756 +3 front 2 back 1 3.78616 +3 front 3 back 2 3.7334 +3 front 3 back 1 3.68208 diff --git a/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat.unity b/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat.unity new file mode 100644 index 0000000..b7b2b5f --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/27Al/backgains.dat.unity @@ -0,0 +1,96 @@ +1 0 0 1. +1 1 0 1. +1 2 0 1. +1 3 0 1. +1 0 1 1. +1 1 1 1. +1 2 1 1. +1 3 1 1. +1 0 2 1. +1 1 2 1. +1 2 2 1. +1 3 2 1. +1 0 3 1. +1 1 3 1. +1 2 3 1. +1 3 3 1. +7 0 0 1. +7 1 0 1. +7 2 0 1. +7 3 0 1. +7 0 1 1. +7 1 1 1. +7 2 1 1. +7 3 1 1. +7 0 2 1. +7 1 2 1. +7 2 2 1. +7 3 2 1. +7 0 3 1. +7 1 3 1. +7 2 3 1. +7 3 3 1. +0 0 0 1. +0 1 0 1. +0 2 0 1. +0 3 0 1. +0 0 1 1. +0 1 1 1. +0 2 1 1. +0 3 1 1. +0 0 2 1. +0 1 2 1. +0 2 2 1. +0 3 2 1. +0 0 3 1. +0 1 3 1. +0 2 3 1. +0 3 3 1. +2 0 0 1. +2 1 0 1. +2 2 0 1. +2 3 0 1. +2 0 1 1. +2 1 1 1. +2 2 1 1. +2 3 1 1. +2 0 2 1. +2 1 2 1. +2 2 2 1. +2 3 2 1. +2 0 3 1. +2 1 3 1. +2 2 3 1. +2 3 3 1. +9 0 0 1. +9 1 0 1. +9 2 0 1. +9 3 0 1. +9 0 1 1. +9 1 1 1. +9 2 1 1. +9 3 1 1. +9 0 2 1. +9 1 2 1. +9 2 2 1. +9 3 2 1. +9 0 3 1. +9 1 3 1. +9 2 3 1. +9 3 3 1. +3 0 0 1. +3 1 0 1. +3 2 0 1. +3 3 0 1. +3 0 1 1. +3 1 1 1. +3 2 1 1. +3 3 1 1. +3 0 2 1. +3 1 2 1. +3 2 2 1. +3 3 2 1. +3 0 3 1. +3 1 3 1. +3 2 3 1. +3 3 3 1. diff --git a/anasen_analysis_vignesh/sx3cal/27Al/frontgains.dat b/anasen_analysis_vignesh/sx3cal/27Al/frontgains.dat new file mode 100644 index 0000000..e1519c5 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/27Al/frontgains.dat @@ -0,0 +1,16 @@ +1 lengthcal front 0 0.878906 58.5938 +1 lengthcal front 1 1.42045 56.8182 +1 lengthcal front 2 -2.55682 56.8182 +1 lengthcal front 3 2.55682 56.8182 +7 lengthcal front 0 0.425806 42.5806 +7 lengthcal front 1 1.92004 45.1774 +7 lengthcal front 2 1.11607 44.6429 +7 lengthcal front 3 3.45909 44.6334 +9 lengthcal front 0 1.82872 45.7181 +9 lengthcal front 1 1.01649 45.1774 +9 lengthcal front 2 1.46827 45.1774 +9 lengthcal front 3 2.54513 46.2751 +3 lengthcal front 0 0. 50. +3 lengthcal front 1 1.1713 58.5652 +3 lengthcal front 2 -3.07505 58.5723 +3 lengthcal front 3 4.0726 60.3348 diff --git a/anasen_analysis_vignesh/sx3cal/27Al/frontgains.dat.unity b/anasen_analysis_vignesh/sx3cal/27Al/frontgains.dat.unity new file mode 100644 index 0000000..a6df93c --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/27Al/frontgains.dat.unity @@ -0,0 +1,24 @@ +9 temp temp 0 0. 1. +9 temp temp 1 0. 1. +9 temp temp 2 0. 1. +9 temp temp 3 0. 1. +7 temp temp 0 0. 1. +7 temp temp 1 0. 1. +7 temp temp 2 0. 1. +7 temp temp 3 0. 1. +1 temp temp 0 0. 1. +1 temp temp 1 0. 1. +1 temp temp 2 0. 1. +1 temp temp 3 0. 1. +2 temp temp 0 0. 1. +2 temp temp 1 0. 1. +2 temp temp 2 0. 1. +2 temp temp 3 0. 1. +0 temp temp 0 0. 1. +0 temp temp 1 0. 1. +0 temp temp 2 0. 1. +0 temp temp 3 0. 1. +3 temp temp 0 0. 1. +3 temp temp 1 0. 1. +3 temp temp 2 0. 1. +3 temp temp 3 0. 1. diff --git a/anasen_analysis_vignesh/sx3cal/27Al/rightgains.dat b/anasen_analysis_vignesh/sx3cal/27Al/rightgains.dat new file mode 100644 index 0000000..374c899 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/27Al/rightgains.dat @@ -0,0 +1,16 @@ +1 0 1221.23 0.648782 +1 1 1819.66 1.06196 +1 2 1860.02 1.11979 +1 3 1825.44 0.964989 +7 0 1609.63 1.04668 +7 1 1734.45 1.12285 +7 2 1538.97 1.0486 +7 3 1524.57 0.951587 +9 0 1672.38 1.11321 +9 1 1542.13 1.01442 +9 2 1540.38 0.967847 +9 3 1560.42 0.969022 +3 0 1000.0 1. +3 1 1539.42 1.0422 +3 2 1720.12 1.31534 +3 3 1562.16 1.00415 diff --git a/anasen_analysis_vignesh/sx3cal/27Al/rightgains.dat.unity b/anasen_analysis_vignesh/sx3cal/27Al/rightgains.dat.unity new file mode 100644 index 0000000..2f7a305 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/27Al/rightgains.dat.unity @@ -0,0 +1,24 @@ +9 0 1000 1.0 +9 1 1000 1.0 +9 2 1000 1.0 +9 3 1000 1.0 +7 0 1000 1.0 +7 1 1000 1.0 +7 2 1000 1.0 +7 3 1000 1.0 +2 0 1000 1.0 +2 1 1000 1.0 +2 2 1000 1.0 +2 3 1000 1.0 +0 0 1000 1.0 +0 1 1000 1.0 +0 2 1000 1.0 +0 3 1000 1.0 +1 0 1000 1.0 +1 1 1000 1.0 +1 2 1000 1.0 +1 3 1000 1.0 +3 0 1000 1.0 +3 1 1000 1.0 +3 2 1000 1.0 +3 3 1000 1.0 diff --git a/anasen_analysis_vignesh/sx3cal/EXFit.C b/anasen_analysis_vignesh/sx3cal/EXFit.C new file mode 100644 index 0000000..6a4e13f --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/EXFit.C @@ -0,0 +1,67 @@ +{ + int index = 1; + TFile *f = new TFile("../results_run01.root"); + TH2F *h2=NULL; + TH1F *h1x=NULL, *h1y=NULL; + //f->cd("evsx"); + //f->ls(); + + double known_xpos[2][2] = {{0,18.75},{-18.75,0}}; + std::vector xpos, xposkn; //first = x = known position, second = y = unknown position + + std::ofstream ofb(Form("backgains%d.dat",index)); + std::ofstream off(Form("frontgains%d.dat",index)); + for(int i=0; i<4; i++) { + //do it for pad#2 + int backnum=2; + h2 = (TH2F*)(f->Get(Form("evsx/be_vs_x_sx3_id_%d_f%d_b%d",index,i,backnum))); + auto macro = [&]() { + h1x = (TH1F*)(h2->ProjectionX("_px")); + double xleft = h1x->GetBinCenter(h1x->FindFirstBinAbove(h1x->GetMaximum()*0.4)); + double xright = h1x->GetBinCenter(h1x->FindLastBinAbove(h1x->GetMaximum()*0.4)); + //h1x->GetXaxis()->SetRangeUser(4*xleft, xright*4); + h1x->Draw(); + TLine L1(xleft,0,xleft,h1x->GetMaximum()); L1.SetLineColor(kRed); L1.Draw("SAME"); + TLine L2(xright,0,xright,h1x->GetMaximum()); L2.SetLineColor(kRed); L2.Draw("SAME"); + gPad->Modified(); + gPad->Update(); + xpos.push_back(xleft); xposkn.push_back(known_xpos[backnum-1][0]); + xpos.push_back(xright); xposkn.push_back(known_xpos[backnum-1][1]); + while(gPad->WaitPrimitive()); + + h1y = (TH1F*)(h2->ProjectionY("_py")); + double ycenter = h1y->GetBinCenter(h1y->GetMaximumBin()); +// std::cout << "front " << i << " back " << backnum << " " << xleft << " " << xright << " " << ycenter << " " << 5486/ycenter << std::endl; + ofb << index <<" front " << i << " back " << backnum << " " << 5486/ycenter << std::endl; + h1y->GetXaxis()->SetRangeUser(ycenter-200,ycenter+200); + h1y->Draw(); + TLine L3(ycenter,0,ycenter,h1y->GetMaximum()*1.1); L3.SetLineColor(kRed); L3.Draw("SAME"); + + gPad->Modified(); + gPad->Update(); + while(gPad->WaitPrimitive()); + }; + if(h2) + macro(); + + //repeat for pad#1 + backnum=1; + h2 = (TH2F*)(f->Get(Form("evsx/be_vs_x_sx3_id_%d_f%d_b%d",index,i,backnum))); + if(h2) + macro(); + + double xtofit[] = {xpos[0],xpos[3]}; + double xktofit[] = {xposkn[0],xposkn[3]}; + TGraph G1(xpos.size(),xpos.data(),xposkn.data()); + G1.Draw("APL*"); + G1.Fit("pol1","Q"); + off << index<<" lengthcal front " << i << " " << G1.GetFunction("pol1")->GetParameter(0) << " " << G1.GetFunction("pol1")->GetParameter(1) << std::endl; + gPad->Modified(); gPad->Update(); + while(gPad->WaitPrimitive()); + xpos.clear(); + xposkn.clear(); + } + ofb.close(); + off.close(); + f->Close(); +} diff --git a/anasen_analysis_vignesh/sx3cal/EXFit2.C b/anasen_analysis_vignesh/sx3cal/EXFit2.C new file mode 100644 index 0000000..0d2ca9f --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/EXFit2.C @@ -0,0 +1,79 @@ +{ + int index = 9; + TFile *f = new TFile("../results_run05.root"); + TH2F *h2=NULL; + TH1F *h1x=NULL, *h1y=NULL; + //f->cd("evsx"); + //f->ls(); + + double known_xpos[4][2] = {{0,18.75},{-18.75,0}}; + std::vector xpos, xposkn; //first = x = known position, second = y = unknown position + + std::ofstream ofb(Form("backgains%d.dat",index)); + std::ofstream off(Form("frontgains%d.dat",index)); + for(int i=0; i<4; i++) { + //do it for pad#2 + int backnum=2; + h2 = (TH2F*)(f->Get(Form("evsx/be_vs_x_sx3_id_%d_f%d_b%d",index,i,backnum))); + auto macro = [&]() { + h1x = (TH1F*)(h2->ProjectionX("_px")); + double xleft = h1x->GetBinCenter(h1x->FindFirstBinAbove(h1x->GetMaximum()*0.4)); + double xright = h1x->GetBinCenter(h1x->FindLastBinAbove(h1x->GetMaximum()*0.4)); + //h1x->GetXaxis()->SetRangeUser(4*xleft, xright*4); + h1x->Draw(); + TLine L1(xleft,0,xleft,h1x->GetMaximum()); L1.SetLineColor(kRed); L1.Draw("SAME"); + TLine L2(xright,0,xright,h1x->GetMaximum()); L2.SetLineColor(kRed); L2.Draw("SAME"); + gPad->Modified(); + gPad->Update(); + if(backnum==1 || backnum==2) xpos.push_back(xleft); xposkn.push_back(known_xpos[backnum-1][0]); + if(backnum==1 || backnum==2) xpos.push_back(xright); xposkn.push_back(known_xpos[backnum-1][1]); + while(gPad->WaitPrimitive()); + + h1y = (TH1F*)(h2->ProjectionY("_py")); + double ycenter = h1y->GetBinCenter(h1y->GetMaximumBin()); +// std::cout << "front " << i << " back " << backnum << " " << xleft << " " << xright << " " << ycenter << " " << 5486/ycenter << std::endl; + ofb << index <<" front " << i << " back " << backnum << " " << 5486/ycenter << std::endl; + h1y->GetXaxis()->SetRangeUser(ycenter-200,ycenter+200); + h1y->Draw(); + TLine L3(ycenter,0,ycenter,h1y->GetMaximum()*1.1); L3.SetLineColor(kRed); L3.Draw("SAME"); + + gPad->Modified(); + gPad->Update(); + while(gPad->WaitPrimitive()); + }; + if(h2) + macro(); + + //repeat for pad#1 + backnum=1; + h2 = (TH2F*)(f->Get(Form("evsx/be_vs_x_sx3_id_%d_f%d_b%d",index,i,backnum))); + if(h2) + macro(); + + //repeat for pad#2 + backnum=3; + h2 = (TH2F*)(f->Get(Form("evsx/be_vs_x_sx3_id_%d_f%d_b%d",index,i,backnum))); + if(h2) + macro(); + + //repeat for pad3 + backnum=0; + h2 = (TH2F*)(f->Get(Form("evsx/be_vs_x_sx3_id_%d_f%d_b%d",index,i,backnum))); + if(h2) + macro(); + + double xtofit[] = {xpos[0],xpos[3]}; + double xktofit[] = {xposkn[0],xposkn[3]}; + TGraph G1(xpos.size(),xpos.data(),xposkn.data()); + G1.Draw("APL*"); + G1.Fit("pol1","Q"); + off << index<<" lengthcal front " << i << " " << G1.GetFunction("pol1")->GetParameter(0) << " " << G1.GetFunction("pol1")->GetParameter(1) << std::endl; + gPad->Modified(); gPad->Update(); + while(gPad->WaitPrimitive()); + xpos.clear(); + xposkn.clear(); + } + ofb.close(); + off.close(); + f->Close(); +} diff --git a/anasen_analysis_vignesh/sx3cal/LRFit.C b/anasen_analysis_vignesh/sx3cal/LRFit.C new file mode 100644 index 0000000..a52e23b --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/LRFit.C @@ -0,0 +1,37 @@ +{ + TFile *f = new TFile("../results_run01.root"); + f->cd("l_vs_r"); + gDirectory->ls(); + int clkpos = 1; + std::ofstream ofile(Form("rightgains%d.dat",clkpos)); + for(int i=0; i<4; i++) { + TH2F h2(*(TH2F*)(f->Get(Form("l_vs_r/l_vs_r_sx3_id_%d_f%d",clkpos,i)))); + h2.Draw(); + + TH1F hproj(*(TH1F*)(h2.ProjectionX("_px"))); + /*hproj.Draw("SAME"); + gPad->Modified(); + gPad->Update(); + while(gPad->WaitPrimitive());*/ + + int leftbin = hproj.FindFirstBinAbove(hproj.GetMaximum()*0.4); + int rightbin = hproj.FindLastBinAbove(hproj.GetMaximum()*0.1); + + TH1F h1(*(TH1F*)(h2.ProfileX("_pfx",leftbin,rightbin))); + h1.Draw("histo same"); + TLine L1(h1.GetBinCenter(leftbin),0,h1.GetBinCenter(leftbin),1000); L1.SetLineColor(kRed); L1.Draw("SAME"); + TLine L2(h1.GetBinCenter(rightbin),0,h1.GetBinCenter(rightbin),1000); L2.SetLineColor(kRed); L2.Draw("SAME"); + //h2.GetYaxis()->SetRangeUser(0,2000); + //h2.GetXaxis()->SetRangeUser(hproj.GetBinCenter(leftbin),hproj.GetBinCenter(rightbin)); + h2.Fit("pol1","","SAME",h1.GetBinCenter(leftbin),h1.GetBinCenter(rightbin)); + + TF1 *f1 = (TF1*)h2.GetFunction("pol1"); + f1->Draw("SAME"); + ofile << clkpos << " " << i << " " << f1->GetParameter(0) << " " << TMath::Abs(f1->GetParameter(1)) << std::endl; + gPad->Modified(); + gPad->Update(); + while(gPad->WaitPrimitive()); + } + ofile.close(); + f->Close(); +} diff --git a/anasen_analysis_vignesh/sx3cal/backgains.dat.unity b/anasen_analysis_vignesh/sx3cal/backgains.dat.unity new file mode 100644 index 0000000..f8b48b9 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/backgains.dat.unity @@ -0,0 +1,80 @@ +1 0 0 1. +1 1 0 1. +1 2 0 1. +1 3 0 1. +1 0 1 1. +1 1 1 1. +1 2 1 1. +1 3 1 1. +1 0 2 1. +1 1 2 1. +1 2 2 1. +1 3 2 1. +1 0 3 1. +1 1 3 1. +1 2 3 1. +1 3 3 1. +7 0 0 1. +7 1 0 1. +7 2 0 1. +7 3 0 1. +7 0 1 1. +7 1 1 1. +7 2 1 1. +7 3 1 1. +7 0 2 1. +7 1 2 1. +7 2 2 1. +7 3 2 1. +7 0 3 1. +7 1 3 1. +7 2 3 1. +7 3 3 1. +0 0 0 1. +0 1 0 1. +0 2 0 1. +0 3 0 1. +0 0 1 1. +0 1 1 1. +0 2 1 1. +0 3 1 1. +0 0 2 1. +0 1 2 1. +0 2 2 1. +0 3 2 1. +0 0 3 1. +0 1 3 1. +0 2 3 1. +0 3 3 1. +2 0 0 1. +2 1 0 1. +2 2 0 1. +2 3 0 1. +2 0 1 1. +2 1 1 1. +2 2 1 1. +2 3 1 1. +2 0 2 1. +2 1 2 1. +2 2 2 1. +2 3 2 1. +2 0 3 1. +2 1 3 1. +2 2 3 1. +2 3 3 1. +9 0 0 1. +9 1 0 1. +9 2 0 1. +9 3 0 1. +9 0 1 1. +9 1 1 1. +9 2 1 1. +9 3 1 1. +9 0 2 1. +9 1 2 1. +9 2 2 1. +9 3 2 1. +9 0 3 1. +9 1 3 1. +9 2 3 1. +9 3 3 1. diff --git a/anasen_analysis_vignesh/sx3cal/backgains1.dat b/anasen_analysis_vignesh/sx3cal/backgains1.dat new file mode 100644 index 0000000..8697b5f --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/backgains1.dat @@ -0,0 +1,12 @@ +1 front 0 back 2 4.44599 +1 front 0 back 3 3.68208 +1 front 0 back 0 3.89631 +1 front 1 back 2 4.44599 +1 front 1 back 3 3.81311 +1 front 1 back 0 3.98321 +1 front 2 back 2 4.52103 +1 front 2 back 3 3.68208 +1 front 2 back 0 3.95382 +1 front 3 back 2 4.55951 +1 front 3 back 3 3.68208 +1 front 3 back 0 3.89631 diff --git a/anasen_analysis_vignesh/sx3cal/backgains3.dat b/anasen_analysis_vignesh/sx3cal/backgains3.dat new file mode 100644 index 0000000..f42a32d --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/backgains3.dat @@ -0,0 +1,12 @@ +3 front 1 back 2 3.81311 +3 front 1 back 1 3.92485 +3 front 1 back 3 4.13701 +3 front 1 back 0 4.26886 +3 front 2 back 2 3.86817 +3 front 2 back 1 4.04334 +3 front 2 back 3 3.98321 +3 front 2 back 0 4.23512 +3 front 3 back 2 3.92485 +3 front 3 back 1 3.92485 +3 front 3 back 3 3.95382 +3 front 3 back 0 4.13701 diff --git a/anasen_analysis_vignesh/sx3cal/backgains4.dat b/anasen_analysis_vignesh/sx3cal/backgains4.dat new file mode 100644 index 0000000..577b88c --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/backgains4.dat @@ -0,0 +1,2 @@ +4 front 0 back 3 3.33796 +4 front 0 back 0 3.29688 diff --git a/anasen_analysis_vignesh/sx3cal/backgains5.dat b/anasen_analysis_vignesh/sx3cal/backgains5.dat new file mode 100644 index 0000000..e69de29 diff --git a/anasen_analysis_vignesh/sx3cal/backgains7.dat b/anasen_analysis_vignesh/sx3cal/backgains7.dat new file mode 100644 index 0000000..1fb1bfe --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/backgains7.dat @@ -0,0 +1,16 @@ +7 front 0 back 2 3.65694 +7 front 0 back 1 3.53625 +7 front 0 back 3 4.23512 +7 front 0 back 0 3.60769 +7 front 1 back 2 3.65694 +7 front 1 back 1 3.53625 +7 front 1 back 3 4.23512 +7 front 1 back 0 3.58356 +7 front 2 back 2 3.68208 +7 front 2 back 1 3.55975 +7 front 2 back 3 4.13701 +7 front 2 back 0 3.60769 +7 front 3 back 2 3.68208 +7 front 3 back 1 3.53625 +7 front 3 back 3 4.23512 +7 front 3 back 0 3.58356 diff --git a/anasen_analysis_vignesh/sx3cal/backgains8.dat b/anasen_analysis_vignesh/sx3cal/backgains8.dat new file mode 100644 index 0000000..e69de29 diff --git a/anasen_analysis_vignesh/sx3cal/backgains9.dat b/anasen_analysis_vignesh/sx3cal/backgains9.dat new file mode 100644 index 0000000..a674cb3 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/backgains9.dat @@ -0,0 +1,16 @@ +9 front 0 back 2 3.68208 +9 front 0 back 1 3.53625 +9 front 0 back 3 3.51306 +9 front 0 back 0 3.42327 +9 front 1 back 2 3.70756 +9 front 1 back 1 3.49018 +9 front 1 back 3 3.63215 +9 front 1 back 0 3.46759 +9 front 2 back 2 3.70756 +9 front 2 back 1 3.55975 +9 front 2 back 3 3.53625 +9 front 2 back 0 3.44529 +9 front 3 back 2 3.7334 +9 front 3 back 1 3.51306 +9 front 3 back 3 3.53625 +9 front 3 back 0 3.42327 diff --git a/anasen_analysis_vignesh/sx3cal/frontgains.dat.unity b/anasen_analysis_vignesh/sx3cal/frontgains.dat.unity new file mode 100644 index 0000000..7f21ff5 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/frontgains.dat.unity @@ -0,0 +1,20 @@ +9 temp temp 0 0. 1. +9 temp temp 1 0. 1. +9 temp temp 2 0. 1. +9 temp temp 3 0. 1. +7 temp temp 0 0. 1. +7 temp temp 1 0. 1. +7 temp temp 2 0. 1. +7 temp temp 3 0. 1. +1 temp temp 0 0. 1. +1 temp temp 1 0. 1. +1 temp temp 2 0. 1. +1 temp temp 3 0. 1. +2 temp temp 0 0. 1. +2 temp temp 1 0. 1. +2 temp temp 2 0. 1. +2 temp temp 3 0. 1. +0 temp temp 0 0. 1. +0 temp temp 1 0. 1. +0 temp temp 2 0. 1. +0 temp temp 3 0. 1. diff --git a/anasen_analysis_vignesh/sx3cal/frontgains1.dat b/anasen_analysis_vignesh/sx3cal/frontgains1.dat new file mode 100644 index 0000000..d077596 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/frontgains1.dat @@ -0,0 +1,4 @@ +1 lengthcal front 0 -0.292969 58.5938 +1 lengthcal front 1 0.302419 60.4839 +1 lengthcal front 2 -2.55682 56.8182 +1 lengthcal front 3 2.72177 60.4839 diff --git a/anasen_analysis_vignesh/sx3cal/frontgains3.dat b/anasen_analysis_vignesh/sx3cal/frontgains3.dat new file mode 100644 index 0000000..06c92a4 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/frontgains3.dat @@ -0,0 +1,3 @@ +3 lengthcal front 1 0.468555 62.474 +3 lengthcal front 2 -3.17087 60.3975 +3 lengthcal front 3 5.24289 63.5502 diff --git a/anasen_analysis_vignesh/sx3cal/frontgains4.dat b/anasen_analysis_vignesh/sx3cal/frontgains4.dat new file mode 100644 index 0000000..e69de29 diff --git a/anasen_analysis_vignesh/sx3cal/frontgains5.dat b/anasen_analysis_vignesh/sx3cal/frontgains5.dat new file mode 100644 index 0000000..e69de29 diff --git a/anasen_analysis_vignesh/sx3cal/frontgains7.dat b/anasen_analysis_vignesh/sx3cal/frontgains7.dat new file mode 100644 index 0000000..b14ca98 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/frontgains7.dat @@ -0,0 +1,4 @@ +7 lengthcal front 0 0 44.0628 +7 lengthcal front 1 1.68159 48.0453 +7 lengthcal front 2 0.80963 46.2646 +7 lengthcal front 3 3.5855 46.2646 diff --git a/anasen_analysis_vignesh/sx3cal/frontgains8.dat b/anasen_analysis_vignesh/sx3cal/frontgains8.dat new file mode 100644 index 0000000..e69de29 diff --git a/anasen_analysis_vignesh/sx3cal/frontgains9.dat b/anasen_analysis_vignesh/sx3cal/frontgains9.dat new file mode 100644 index 0000000..88d4750 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/frontgains9.dat @@ -0,0 +1,4 @@ +9 lengthcal front 0 2.10937 46.875 +9 lengthcal front 1 0.57866 46.2928 +9 lengthcal front 2 1.17187 46.875 +9 lengthcal front 3 1.6345 46.6999 diff --git a/anasen_analysis_vignesh/sx3cal/rightgains.dat.unity b/anasen_analysis_vignesh/sx3cal/rightgains.dat.unity new file mode 100644 index 0000000..45ffe55 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/rightgains.dat.unity @@ -0,0 +1,20 @@ +9 0 1000 1.0 +9 1 1000 1.0 +9 2 1000 1.0 +9 3 1000 1.0 +7 0 1000 1.0 +7 1 1000 1.0 +7 2 1000 1.0 +7 3 1000 1.0 +2 0 1000 1.0 +2 1 1000 1.0 +2 2 1000 1.0 +2 3 1000 1.0 +0 0 1000 1.0 +0 1 1000 1.0 +0 2 1000 1.0 +0 3 1000 1.0 +1 0 1000 1.0 +1 1 1000 1.0 +1 2 1000 1.0 +1 3 1000 1.0 diff --git a/anasen_analysis_vignesh/sx3cal/rightgains1.dat b/anasen_analysis_vignesh/sx3cal/rightgains1.dat new file mode 100644 index 0000000..ead1cd0 --- /dev/null +++ b/anasen_analysis_vignesh/sx3cal/rightgains1.dat @@ -0,0 +1,4 @@ +1 0 1229.18 1.00572 +1 1 1765.87 0.968534 +1 2 1778.36 0.877985 +1 3 1843.61 0.985871