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在基于白光中子源的中子核反应测量中, 伴随中子束的伽马射线是重要的实验本底之一. 本文对中国散裂中子源反角白光中子源的束内伽马射线进行了研究. 通过蒙特卡罗模拟, 得到了伽马射线的能量分布和时间结构. 通过直接测量和间接测量两种方法测得低能中子区的束内伽马射线的时间结构. 直接测量实验中, 将载6Li的ZnS(Ag)闪烁体探测器置于束流线上, 通过飞行时间法直接测量束内的中子和伽马射线的时间结构, 并利用波形甄别技术进行粒子鉴别. 间接测量法是将铅样品置于束流线上, 利用C6D6闪烁体探测器测量样品上的散射伽马射线, 从而得到入射伽马射线的时间结构. 实验测量结果与模拟结果在12 μs—2.0 ms的时间区间内具有较好的一致性.The back-streaming neutron beam line (Back-n) was built in the beginning of 2018, which is part of the China Spallation Neutron Source (CSNS). The Back-n is the first white neutron beam line in China, and its main application is for nuclear data measurement. For most of neutron-induced nuclear reaction measurements based on white neutron facilities, the beam of gamma rays accompanied with neutron beam is one of the most important experimental backgrounds. The back streaming neutron beam is transported directly from the spallation target to the experimental station without any moderator or shielding, the flux of the in-beam gamma rays in the experimental station is much larger than those of these facilities with neutron moderator and shielding. Therefore, it is necessary to consider the influence of in-beam gamma rays on the experimental results. Studies of the in-beam gamma rays are carried out at the back-n. Monte-Carlo simulation is employed to obtain the energy distribution and the time structure of the in-beam gamma rays. According to the simulation results, when the neutron flight time is longer than 1.0 μs the energy distribution of the in-beam gamma rays does not vary with flight time. Therefore, the time structure of these gamma rays can be measured without the correction of the detection efficiency. In this work, the time structure of the in-beam gamma rays in the low neutron energy region is measured by both direct and indirect methods. In the direct measurement, a 6Li loaded ZnS(Ag) scintillator is located on the neutron beam line and the time of flight method is used to determine the time structure of neutrons and gamma rays. The gamma rays are separated from neutrons with pulse-shape discrimination. The black filter method is used to verify the particle discrimination results. In the indirect measurement, the C6D6 scintillation detectors are used to measure the gamma rays scattered off a Pb sample on the way of the neutron beam. The time structure of the in-beam gamma rays is derived from that of the scattered gamma rays. The experimental results are in good agreement with the simulations with the time-of-flight between 12 μs and 2.0 ms. Besides, according to the simulation results, the intensity of the in-beam gamma rays is 1.21 × 106 s–1·cm–2 in the center of the experimental station 2 of Back-n, which is 76.5 m away from the spallation target of CSNS.
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Keywords:
- back-streaming white neutron source /
- in-beam γ-rays measurement /
- time of flight method /
- Monte-Carlo simulation
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表 1 Geant 4中的物理模型
Table 1. Physical models in the Geant 4 code.
粒子类型 能量区间/MeV 物理模型 质子 < 1600 G4HadronModel G4CascadeInterface 中子 < 20.0 G4NeutronHPModel (ENDF/B-VII.1) > 20.0 G4HadronModel 伽马 > 0 G4RayleighScattering G4PhotoElectricEffect G4ComptonScattering G4GammaConversion 电子 > 0 G4eMultipleScattering G4eIonisation G4eBremsstrahlung -
[1] Chen H, Wang X L 2016 Nat. Mater. 15 689Google Scholar
[2] Tang J Y, Fu S N, Jing H T, Tang H Q, Wei J, Xia H H 2010 Chin. Phys. C 34 121Google Scholar
[3] Jing H T, Tang J Y, Tang H Q, Zhang C, Zhou Z Y, Zhong Q P, Ruan X C 2010 Nucl. Instrum. Methods A 621 91Google Scholar
[4] An Q, Bai H Y, Bao J, et al. 2017 J. Instrum 12 P07022
[5] Chen Y H, Luan G Y, Bao J, et al. 2019 Eur. Phys. J. A 55 115Google Scholar
[6] 鲍杰, 陈永浩, 张显鹏竺 2019 68 080101Google Scholar
Bao J, Chen Y H, Zhang X P, et al. 2019 Acta Phys. Sin 68 080101Google Scholar
[7] Li Q, Luan G Y, Bao J, et al. 2019 Nucl. Instrum. Methods A 946 162497Google Scholar
[8] Liu X Y, Yang Y W, Liu R, et al. 2019 Nucl. Sci. Tech 30 139Google Scholar
[9] Yang Y, Wen Z, Han Z, et al. 2019 Nucl. Instrum. Methods A 940 486Google Scholar
[10] Bai H, Fan R, Jiang H, et al. 2020 Chin. Phys. C 44 014003Google Scholar
[11] Jiang H, Jiang W, Bai H, et al. 2019 Chin. Phys. C 43 124002Google Scholar
[12] Briesmeister J F E 2000 MCNP-A General Monte Carlo N-Particle Transport Code (Version 4C) LA-13709-M
[13] Allison J, Amako K, Apostolakis J, et al. 2016 Nucl. Instrum. Methods A 836 186Google Scholar
[14] Bohlen T T, Cerutti F, Chin M P W, Fasso A, Ferrari A, Ortega P G, Mairani A, Sala P R, Smirnov G, Vlachoudis V 2014 Nucl. Data Sheets 120 211Google Scholar
[15] Zhang L Y, Jing H T, Tang J Y, et al. 2018 Appl. Radiat. Isot 132 212Google Scholar
[16] Chadwick M B, Herman M, Oblozinsky P, et al. 2011 Nucl. Data Sheets 112 2887Google Scholar
[17] EJ-420 Data Sheet, https://eljentechnology.com/images/products/data_sheets/EJ-420.pdf/[2020-04-15]
[18] Wang Q, Cao P, Qi X, et al. 2018 Rev. Sci. Instrum 89 013511Google Scholar
[19] Syme D B 1982 Nucl. Instrum. Methods 198 357Google Scholar
[20] Ren J, Ruan X C, Bao J, et al. 2019 Radiation Detection Technology and Methods 3 52Google Scholar
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