Numerical Simulation of Radiation Anisotropy of the Pyroelectric Neutron Generator

M. B. Gromov; A. S. Kubankin; V. Y. Ionidi; A. A. Kaplii; M. A. Kirsanov; A. A. Klenin; D. A. Kolesnikov; A. N. Oleinik; A. S. Chepurnov; A. V. Shchagin

doi:10.3103/S0027134919020085

Numerical Simulation of Radiation Anisotropy of the Pyroelectric Neutron Generator

M. B. Gromov, A. S. Kubankin, V. Y. Ionidi, A. A. Kaplii, M. A. Kirsanov, A. A. Klenin, D. A. Kolesnikov, A. N. Oleinik, A. S. Chepurnov, A. V. Shchagin

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Abstract

The pyroelectric neutron generator is a compact source of fast neutrons with an energy of 2.45 MeV and a yield up to ∼10⁴ neutrons/s. The device is designed for calibration of low-background neutrino and dark matter detectors and may also serve as an alternative to traditional radioactive sources of fast neutrons in physical research and practical work. Numerical simulation of the angular distribution of neutrons emitted by the pyroelectric generator with the D(d, n)³He reaction proceeding within it was performed in order to calculate the neutron yield in the full solid angle and in a given direction correctly. The angular distribution was found to be anisotropic: the neutron yield increased in the direction of motion of incident deuterium ions. This anisotropy was as large as ∼25% at a maximum energy of 28 keV of incident particles. The anisotropy increased nonlinearly with the ion energy: it reached ∼70% at 50 keV and a monoenergetic flux, but was virtually zero below 10 keV. The obtained angular distribution is similar to that of neutrons in the case of a 15-keV monoenergetic flux of deuterium ions.

Original language	English
Pages (from-to)	144-148
Number of pages	5
Journal	Moscow University Physics Bulletin
Volume	74
Issue number	2
Early online date	11 Jun 2019
DOIs	https://doi.org/10.3103/S0027134919020085
Publication status	E-pub ahead of print - 11 Jun 2019

Keywords

angular distribution
anisotropy
Borexino
calibration
DarkSide
JUNO
low-background detectors
neutrons
pyroelectric neutron generator

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10.3103/S0027134919020085

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Gromov, M. B., Kubankin, A. S., Ionidi, V. Y., Kaplii, A. A., Kirsanov, M. A., Klenin, A. A., Kolesnikov, D. A., Oleinik, A. N., Chepurnov, A. S., & Shchagin, A. V. (2019). Numerical Simulation of Radiation Anisotropy of the Pyroelectric Neutron Generator. Moscow University Physics Bulletin, 74(2), 144-148. Advance online publication. https://doi.org/10.3103/S0027134919020085

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abstract = "The pyroelectric neutron generator is a compact source of fast neutrons with an energy of 2.45 MeV and a yield up to ∼104 neutrons/s. The device is designed for calibration of low-background neutrino and dark matter detectors and may also serve as an alternative to traditional radioactive sources of fast neutrons in physical research and practical work. Numerical simulation of the angular distribution of neutrons emitted by the pyroelectric generator with the D(d, n)3He reaction proceeding within it was performed in order to calculate the neutron yield in the full solid angle and in a given direction correctly. The angular distribution was found to be anisotropic: the neutron yield increased in the direction of motion of incident deuterium ions. This anisotropy was as large as ∼25% at a maximum energy of 28 keV of incident particles. The anisotropy increased nonlinearly with the ion energy: it reached ∼70% at 50 keV and a monoenergetic flux, but was virtually zero below 10 keV. The obtained angular distribution is similar to that of neutrons in the case of a 15-keV monoenergetic flux of deuterium ions.",

keywords = "angular distribution, anisotropy, Borexino, calibration, DarkSide, JUNO, low-background detectors, neutrons, pyroelectric neutron generator",

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AU - Ionidi, V. Y.

AU - Kaplii, A. A.

AU - Kirsanov, M. A.

AU - Klenin, A. A.

AU - Kolesnikov, D. A.

AU - Oleinik, A. N.

AU - Chepurnov, A. S.

AU - Shchagin, A. V.

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N2 - The pyroelectric neutron generator is a compact source of fast neutrons with an energy of 2.45 MeV and a yield up to ∼104 neutrons/s. The device is designed for calibration of low-background neutrino and dark matter detectors and may also serve as an alternative to traditional radioactive sources of fast neutrons in physical research and practical work. Numerical simulation of the angular distribution of neutrons emitted by the pyroelectric generator with the D(d, n)3He reaction proceeding within it was performed in order to calculate the neutron yield in the full solid angle and in a given direction correctly. The angular distribution was found to be anisotropic: the neutron yield increased in the direction of motion of incident deuterium ions. This anisotropy was as large as ∼25% at a maximum energy of 28 keV of incident particles. The anisotropy increased nonlinearly with the ion energy: it reached ∼70% at 50 keV and a monoenergetic flux, but was virtually zero below 10 keV. The obtained angular distribution is similar to that of neutrons in the case of a 15-keV monoenergetic flux of deuterium ions.

AB - The pyroelectric neutron generator is a compact source of fast neutrons with an energy of 2.45 MeV and a yield up to ∼104 neutrons/s. The device is designed for calibration of low-background neutrino and dark matter detectors and may also serve as an alternative to traditional radioactive sources of fast neutrons in physical research and practical work. Numerical simulation of the angular distribution of neutrons emitted by the pyroelectric generator with the D(d, n)3He reaction proceeding within it was performed in order to calculate the neutron yield in the full solid angle and in a given direction correctly. The angular distribution was found to be anisotropic: the neutron yield increased in the direction of motion of incident deuterium ions. This anisotropy was as large as ∼25% at a maximum energy of 28 keV of incident particles. The anisotropy increased nonlinearly with the ion energy: it reached ∼70% at 50 keV and a monoenergetic flux, but was virtually zero below 10 keV. The obtained angular distribution is similar to that of neutrons in the case of a 15-keV monoenergetic flux of deuterium ions.

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Numerical Simulation of Radiation Anisotropy of the Pyroelectric Neutron Generator

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Keywords

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