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Ionization Loss Simulation in Gaps of Fast Neutron Detector Based on 10B Layer and Gaseous Chamber
- Authors: Potashev S.I.1
-
Affiliations:
- Institute for Nuclear Research of Russian Academy of Sciences
- Issue: Vol 86, No 5 (2023)
- Pages: 634-638
- Section: МАТЕРИАЛЫ 6-ОЙ МЕЖДУНАРОДНОЙ КОНФЕРЕНЦИИ “ICPPA-2022”. Элементарные частицы и поля
- Published: 01.09.2023
- URL: https://medjrf.com/0044-0027/article/view/674695
- DOI: https://doi.org/10.31857/S0044002723050355
- EDN: https://elibrary.ru/IFDUYA
- ID: 674695
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Abstract
An ionization loss simulation in several sequent gaps of the neutron detector is performed. It is based on the boron-10 rigid layer converter and gaseous chamber. It was shown that the distribution of ionization losses over gas gaps varies significantly depending on the incident neutron energy. The fact can be used to control the energy of the neutron flux using this detector.
About the authors
S. I. Potashev
Institute for Nuclear Research of Russian Academy of Sciences
Author for correspondence.
Email: potashev@inr.ru
Moscow, Russia
References
- M. Henske, M. Klein, M. Kohli, P. Lennert, G. Modzel, C. Schmidt, and U. Schmidt, Nucl. Instrum. Methods A 686, 151 (2012).
- F. Piscitelli, F. Messi, M. Anastasopoulos, T. Brys, F. Chicken, E. Dian, J. Fuzi, C. Hoglund, G. Kiss, J. Orban, P. Pazmandi, L. Robinson, L. Rosta, S. Schmidt, D. Varga, T. Zsiros, and R. Hall-Wilton, J. Instrum. 12, 03013 (2017).
- Jianrong Zhou, Q. Xiu, X. Zhou, Jianjin Zhou, L. Ma, Ch. J. Schmidt, M. Klein, Y. Xia, L. Zhou, C. Huang, G. Sun, B. Hu, Z. Sun, and Y. Chen, Nucl. Instrum. Methods A 953, 163051 (2020).
- S. I. Potashev, Yu. M. Burmistrov, A. I. Drachev, S. V. Zuyev, S. Kh. Karaevskii, A. A. Kasparov, E. S. Konobeevskii, S. P. Kuznetsov, V. N. Marin, V. N. Ponomarev, and G. V. Solodukhov, J. Surf. Investig. X-ray, Synchrotr. Neutr. Techn. 12, 627 (2018).
- S. I. Potashev, A. A. Afonin, Yu. M. Burmistrov, A. I. Drachev, E. S. Konobeevskii, V. N. Marin, I. V. Meshkov, S. Kh. Karaevskii, A. A. Kasparov, V. N. Ponomarev, G. V. Solodukhov, and S. V. Zuyev, Bull. Russ. Acad. Sci.: Phys. 85, 1068 (2021).
- S. I. Potashev, A. I. Drachev, Yu. Burmistrov, S. Karaevsky, A. Kasparov, V. Ponomarev, and G. Solodukhov, EPJ Web Conf. 231, 05010 (2020).
- А. А. Каспаров, С. И. Поташев, А. А. Афонин, Ю. М. Бурмистров, А. И. Драчев, Изв. РАН. Сер. физ. 85, 694 (2021).
- I. Lehraus, R. Mattehewson, and W. Tejessy, Nucl. Instrum. Methods A 196, 361 (1982).
- S. I. Potashev, A. A. Kasparov, and V. N. Ponomarev, Bull. Russ. Acad. Sci.: Phys. 86, 1079 (2022).
- Tables of Physical Quantities, Еd. by I. K. Kikoin (Atomizdat, Moscow, 1976).
- R. Bevilacqua, F.-J. Hambsch, M. Vidali, I. Ruskov, and L. Lamia, EPJ Web of Conf. 146, 11010 (2017).
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