Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal...

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Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two-layer plastic scintillation detectors used as anticoincidence shield onal Research Nuclear University "MEPhI" (Moscow Engineering Physics Institu International Conference on Particle Physics and Astrophysics (ICPPA 2015) 2015 October 8, Moscow Evgeniy Chasovikov, Irene Arkhangelskaja, Arkdiy Galper, Andrey Arkhangelskij, Maxim Kheymits, Yuriy Yurkin, Aleksey Perfil`ev

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Page 1: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two-layer plastic scintillation detectors used as anticoincidence

shield

National Research Nuclear University "MEPhI" (Moscow Engineering Physics Institute)

International Conference on Particle Physics and Astrophysics (ICPPA 2015)2015 October 8, Moscow

Evgeniy Chasovikov, Irene Arkhangelskaja, Arkdiy Galper, Andrey Arkhangelskij, Maxim Kheymits, Yuriy Yurkin, Aleksey Perfil`ev

Page 2: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

Page 3: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

Page 4: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

1MeV electron energy loss in upper layer of AC top.

Page 5: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

3MeV electron energy loss in upper layer of AC top.

Page 6: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

10MeV electron energy loss in upper layer of AC top.

Page 7: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

30MeV proton energy loss in upper layer of AC top.

Page 8: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

100MeV proton energy loss in upper layer of AC top.

Page 9: Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal insulation and two- layer plastic scintillation detectors used.

Conclusion

• Passage of low-energy charged particles through GAMMA-400 gamma-telescope thermal insulation and two-layer plastic scintillation detectors used as anticoincidence shield was modeled

• 84% of 1 MeV electrons were fully absorbed by thermal insulation• Other modeled particles are absobed by the anti-cincidence systems.• Low-energy charge particle detectors should be put outside of thermal

insulation.

Modeling of low-energy charged particles passage through GAMMA-400 gamma-telescope thermal...

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