Split-Pole Spectrograph: Difference between revisions
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The Split-Pole Spectrograph consists of a reaction chamber, a | The Split-Pole Spectrograph consists of a reaction chamber, a split-pole magnetic spectrograph, ionization chamber, and a plastic scintinatior. | ||
The | The magnet can be rotated from 0 to 55 degrees in the lab. The magnetic field has an upper limit of 14.5 kG. | ||
== Focal plane detector == | == Focal plane detector == | ||
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The '''S'''ilicon '''A'''rray for '''B'''ranching '''R'''atio '''E'''xperiments | The '''S'''ilicon '''A'''rray for '''B'''ranching '''R'''atio '''E'''xperiments | ||
SABRE is a silicon array designed around branching ratio experiments with the SPS. SABRE sits at backwards angles from the target, and covers roughly 30% of 4pi. SABRE has both thick and thin dead-layer detectors, with the thin dead-layer detectors capable of reaching ~200 keV thresholds for protons and deuterons. | |||
https://www.sciencedirect.com/science/article/pii/S0168900221002837 | https://www.sciencedirect.com/science/article/pii/S0168900221002837 |
Revision as of 14:13, 5 October 2022
The Split-Pole Spectrograph consists of a reaction chamber, a split-pole magnetic spectrograph, ionization chamber, and a plastic scintinatior.
The magnet can be rotated from 0 to 55 degrees in the lab. The magnetic field has an upper limit of 14.5 kG.
Focal plane detector
The focal plane detector consists of an ion chamber with a set of delay lines to detect the position of a particle along the focal plane and a plastic scintillator to detect the energy of the incoming particle. Using the energy loss of the particle through the ion chamber with the energy deposited in the scintillator, particles of different charge and mass can be identified.
There are two position sensitive delay lines in the focal plane detector. By reconstructing the particle trajectory using the position information of both delay lines, the resolution can be enhanced by correcting for the kinematic shift of the reaction.
SABRE
The Silicon Array for Branching Ratio Experiments
SABRE is a silicon array designed around branching ratio experiments with the SPS. SABRE sits at backwards angles from the target, and covers roughly 30% of 4pi. SABRE has both thick and thin dead-layer detectors, with the thin dead-layer detectors capable of reaching ~200 keV thresholds for protons and deuterons.
https://www.sciencedirect.com/science/article/pii/S0168900221002837
SPS Experiment Guide
Media:SPS_Experiment_Guide.pdf
Contact
- Jeff Blackmon mailto:blackmon@lsu.edu
- Ingo
- who should be contacted?