SOLARIS_Analysis/Cleopatra/nuclear_data.py

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Python
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2023-04-03 16:03:48 -04:00
#!/usr/local/bin/python3
################################################
import sys
if len(sys.argv) == 1 :
print( "usage :" )
print( "%s AZ [maxEx]" % sys.argv[0] )
print( "e.g. %s 17O --> 17O ground state data" % sys.argv[0])
print( "e.g. %s 20O 5 --> 20O ground state data and excited state < 5 MeV" % sys.argv[0])
exit()
################################################
import pandas as pd
# the API webpage
# https://www-nds.iaea.org/relnsd/vcharthtml/api_v0_guide.html#examples
# the service URL
livechart = "https://nds.iaea.org/relnsd/v0/data?"
import urllib.request
def lc_read_csv(url):
req = urllib.request.Request(url)
req.add_header('User-Agent', 'Mozilla/5.0 (X11; Ubuntu; Linux x86_64; rv:77.0) Gecko/20100101 Firefox/77.0')
return pd.read_csv(urllib.request.urlopen(req))
haha = lc_read_csv(livechart + 'fields=ground_states&nuclides=all')
mp = 938.27208816; #MeV/c^2
mn = 939.56542052;
def FindZ(AZ):
query = livechart + "fields=ground_states&nuclides=" + AZ
temp = lc_read_csv(query);
try :
return temp['z']
except :
return 'na'
def FindSym(Z):
try:
return (haha['symbol'][haha['z']==Z]).iloc[0]
except:
return 'na'
def Mass(A, Z):
try :
BEA = float(haha['binding'][haha['z']==Z][haha['n']==(A-Z)])/1000
return (A-Z)*mn + Z*mp - A * BEA
except :
return -404
def MassSym(AZ):
query = livechart + "fields=ground_states&nuclides=" + AZ
temp = lc_read_csv(query);
Z = temp['z']
N = temp['n']
try :
return Z*mp + N*mn - (Z+N)*temp['binding']/1000
except:
return -404
def Sp(A,Z,a,z):
mA = Mass(A,Z)
mB = Mass(A-a, Z-z)
if z == 0 :
mb = a * mn
elif a == z :
mb = a * mp
else :
mb = Mass(a,z)
if (mB == -404 or mb == -404 or mA == -404) :
return -404
else:
return mB + mb - mA
def Ex(AZ, maxMeV):
query = livechart + "fields=levels&nuclides=" + AZ
tempEx = lc_read_csv(query);
try :
return tempEx[['energy', 'jp']][tempEx['energy']<= maxMeV * 1000]
except:
return -404
def Info(AZ):
query = livechart + "fields=ground_states&nuclides=" + AZ
temp = lc_read_csv(query);
print("============================================== " + AZ )
try :
Z = temp['z'][0]
N = temp['n'][0]
mass = Z*mp + N*mn - (Z+N)*temp['binding']/1000
halfLife = temp['half_life_sec'][0]
print(" A : %3d, Z : %3d, N : %3d, Mass : %.4f MeV" % (Z+N, Z, N, mass))
print("Jpi : %3s, half-live : %s sec" % (temp['jp'][0], halfLife))
print("Sn : %8.3f MeV, Sp : %8.3f MeV" % (Sp(Z+N,Z, 1, 0), Sp(Z+N,Z, 1, 1)))
print("S2n : %8.3f MeV, S2p : %8.3f MeV, Sd : %8.3f MeV" % (Sp(Z+N,Z, 2, 0), Sp(Z+N,Z, 2, 2), Sp(Z+N, Z, 2, 1)))
print("S3n : %8.3f MeV, S3p : %8.3f MeV, St : %8.3f MeV, S(3He) : %8.3f MeV" % (Sp(Z+N,Z, 3, 0), Sp(Z+N,Z, 3, 3), Sp(Z+N, Z, 3, 1), Sp(Z+N, Z, 3, 2)))
print("S4n : %8.3f MeV, S4p : %8.3f MeV, Sa : %8.3f MeV" % (Sp(Z+N,Z, 4, 0), Sp(Z+N,Z, 4, 4), Sp(Z+N, Z, 4, 2)))
print(" magnetic dipole : " + temp['magnetic_dipole'][0] + " mu.N")
print("electric quadruple : " + temp['electric_quadrupole'][0] + " barn")
if halfLife > 0 :
print('------------ decay mode:')
for i in range(1, 4) :
print("%5s %s %%" % (temp["decay_%d" % i][0], temp["decay_%d_%%" % i][0]))
print('--------------------------')
except :
dummy = 1
print("====================================================\n")
#outfile = open("%s.txt" % AZ, "w")
#outfile.write("============================================== " + AZ + "\n")
#try :
# Z = temp['z'][0]
# N = temp['n'][0]
# mass = Z*mp + N*mn - (Z+N)*temp['binding']/1000
# halfLife = temp['half_life_sec'][0]
# outfile.write(" A : %3d, Z : %3d, N : %3d, Mass : %.4f MeV \n" % (Z+N, Z, N, mass))
# outfile.write("Jpi : %3s, half-live : %s sec \n" % (temp['jp'][0], halfLife))
# outfile.write("Sn : %8.3f MeV, Sp : %8.3f MeV \n" % (Sp(Z+N,Z, 1, 0), Sp(Z+N,Z, 1, 1)))
# outfile.write("S2n : %8.3f MeV, S2p : %8.3f MeV, Sd : %8.3f MeV \n" % (Sp(Z+N,Z, 2, 0), Sp(Z+N,Z, 2, 2), Sp(Z+N, Z, 2, 1)))
# outfile.write("S3n : %8.3f MeV, S3p : %8.3f MeV, St : %8.3f MeV, S(3He) : %8.3f MeV \n" % (Sp(Z+N,Z, 3, 0), Sp(Z+N,Z, 3, 3), Sp(Z+N, Z, 3, 1), Sp(Z+N, Z, 3, 2)))
# outfile.write("S4n : %8.3f MeV, S4p : %8.3f MeV, Sa : %8.3f MeV \n" % (Sp(Z+N,Z, 4, 0), Sp(Z+N,Z, 4, 4), Sp(Z+N, Z, 4, 2)))
# outfile.write(" magnetic dipole : " + temp['magnetic_dipole'][0] + " mu.N\n")
# outfile.write("electric quadruple : " + temp['electric_quadrupole'][0] + " barn \n")
# if halfLife > 0 :
# outfile.write('------------ decay mode: \n')
# for i in range(1, 4) :
# outfile.write("%5s %s %% \n" % (temp["decay_%d" % i][0], temp["decay_%d_%%" % i][0]))
# outfile.write('-------------------------\n')
#except :
# dummy = 1
#outfile.write("====================================================\n")
#outfile.close();
#
#infile = open("%s.txt" % AZ, "r")
#Lines = infile.readlines()
#
#for line in Lines:
# print(line.strip("\n"))
#
#infile.close();
################################################
AZ = sys.argv[1];
maxEx = 0;
if len(sys.argv) > 2 :
maxEx = float(sys.argv[2]);
Info(AZ)
if maxEx > 0 :
print( Ex(AZ, float(maxEx)) )