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Calculation and verification for energetic proton energy deposition in spallation target

Zhou Bin Yu Quan-Zhi Hu Zhi-Liang Chen Liang Zhang Xue-Ying Liang Tian-Jiao

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Calculation and verification for energetic proton energy deposition in spallation target

Zhou Bin, Yu Quan-Zhi, Hu Zhi-Liang, Chen Liang, Zhang Xue-Ying, Liang Tian-Jiao
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  • Energy deposition in spallation target induced by energetic protons is the foundation and the premise of the spallation target research. In this paper, several intra-nuclear cascade models including BERTINI, ISABEL, CEM2K and INCL4 contained in MCNPX package, together with FLUKA and PHITS Monte Carlo codes are used to calculate the energy deposition in lead (Pb) and tungsten (W) spallation target impinged by 800, 1000, and 1200 MeV protons. The contributions of different particles to the total energy deposition in the Pb target are obtained and compared with each other as well. The energy deposition distribution caused by 250 MeV protons in the W target is measured with thermoluminescence detectors (TLDs). The results indicate that the calculations from the MCNPX accord with experimental data, verifying that the Monte Carlo code has a high reliability for energy deposition simulation.
      Corresponding author: Yu Quan-Zhi, qzhyu@iphy.ac.cn
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 91226107, 11575289) and the Chinese Academy of Sciences Key Technology Talent Program
    [1]

    Wang F W, Liang T J, Yin W, Yu Q Z, He L H, Tao J Z, Zhu T, Jia X J, Zhang S Y 2013 Sci. China Phys. Mech. Astron. 56 2410Google Scholar

    [2]

    詹文龙, 徐瑚珊 2012 中国科学院院刊 27 375Google Scholar

    Zhan W L, Xu H S 2012 Bul. Ch. Acad. Sci. 27 375Google Scholar

    [3]

    于全芝, 殷雯, 梁天骄 2011 物理学报 60 052501Google Scholar

    Yu Q Z, Yin W, Liang T J 2011 Acta Phys. Sin. 60 052501Google Scholar

    [4]

    Pelowitz D B 2005 MCNPX User’s Manual version 2.5.0 (Los Alamos: Los Alamos National Laboratory)

    [5]

    Tatsuhiko S, Koji N, Norihiro M, Shintaro H, Yosuke I, Shusaku N, Tatsuhiko O, Hiroshi I, Hiroshi N, Tokio F, Keisuke O, Tetsuya K, Satoshi C 2013 J. Nucl. Sci. Technol. 50 913Google Scholar

    [6]

    Alfredo F, Paola R S, Alberto F, Johannes R FLUKA: A Multi-particle Transport Code (Italian National Institute for Nuclear Physics (INFN) and European Organization for Nuclear Research (CERN))

    [7]

    Belyakov-Bodin V I, Kazaritsky V D, Povarov A L, Chuvilo I V, Sherstnev V A 1990 Nucl. Instr. Meth. A 295 140Google Scholar

    [8]

    Belyakov-Bodin V I, Andreev A M, Dubinsky V D, Kazaritsky V D, Povarov A L, Chuvilo I V, Sherstnev V A 1992 Nucl. Instr. Meth. A 314 508Google Scholar

    [9]

    Belyakov-Bodin V I, Andreev A M, Dubinsky V D, Chuvilo I V, Sherstnev V A 1993 Nucl. Instr. Meth. A 335 30Google Scholar

    [10]

    Belyakov-Bodin V I, Azhgirey I L, Degtyarev I I 2007 Nucl. Instr. Meth. A 572 935Google Scholar

    [11]

    Bauer G S, Spitzer H, Holzen G V, Ni L, Hastings J 1998 14th Meeting of the Int. Collaboration on Advanced Neutron Sources, Uitica I L USA, June 14–19, 1998 p229

    [12]

    Filges D, Neef R D, Schaal H 1998 Proc. of the Fourth Workshop on Simulating Accelerator Radiation Environments, Konxville TN USA, September 14–16, 1998 p221

    [13]

    Tietze A 2001 Ph. D. Dissertation (Wuppertal: University of Wuppertal)

    [14]

    Xia J W, Zhan W L, Wei B W, Yuan Y J, Song M T, Zhang W Z, Yang X D, Yuan P, Gao D Q, Zhao H W, Yang X T, Xiao G Q, Man K T, Dang J R, Cai X H, Wang Y F, Tang J Y, Qiao W M, Rao Y N, He Y, Mao L Z, Zhou Z Z 2002 Nucl. Instr. Meth. A 488 11Google Scholar

    [15]

    Detlef F, Frank G 2009 Handbook of Spallation Research: Theory, Experiments and Applications (Weinheim: WILEY-VCH)

    [16]

    奥伯霍弗, 沙尔曼著 (张彤译) 1988 应用热释光剂量学(北京: 中国计量出版社)

    Oberhofer M, Scharmann A (translated by Zhang T) 1988 The Applied Thermoluminescence Dosimetry (Beijing: China Metrology Press)(in Chinese)

    [17]

    赵建兴, 王峰, 唐开勇, 李海俊, 刘大海, 肖无云, 崔辉 2011 核技术 34 103

    Zhao J X, Wang F, Tang K Y, Li H J, Liu D H, Xiao W Y, Cui H 2011 J. Nucl. Tech. 34 103

    [18]

    Massillon-JL G, Gamboa-deBuen I, Brandan M E 2007 J. Phys. D: Appl. Phys. 40 2584Google Scholar

    [19]

    Bilski P, Berger T, Hajek M, Reitz G 2011 Radi Meas. 46 1728Google Scholar

    [20]

    James F Z, http://www.srim.org [2009]

  • 图 1  (a)不同模拟程序对铅靶总能量沉积计算的对比; (b) 铅靶中能量沉积线性密度的轴向分布

    Figure 1.  (a) Comparison of total energy deposition in lead target calculated by different Monte Carlo codes; (b) axial distribution of linear density of energy deposition in lead target.

    图 2  (a)不同模拟程序对钨靶总能量沉积计算的对比; (b)钨靶中能量沉积线性密度分布

    Figure 2.  (a) Comparison of total energy deposition in tungsten target calculated by different Monte Carlo code; (b) axial distribution of linear density of energy deposition in tungsten target.

    图 3  质子在钨靶中的能量沉积测量示意图

    Figure 3.  Schematic of the energy deposition measurement in a tungsten target incident by protons.

    图 4  第一层TLD的剂量读出值

    Figure 4.  TLD dose readouts at the first layer.

    图 5  不同深度的钨靶中质子的平均能量与水等效LET值

    Figure 5.  Average proton energy in the tungsten target and equivalent LET in water.

    图 6  钨靶中TLD的能量沉积测量值与计算值

    Figure 6.  Energy deposition comparison between measurement and calculation of TLD in tungsten target.

    表 1  CEM2K级联模型计算质子入射铅靶产生的不同粒子对总能量沉积的占比贡献

    Table 1.  The calculated contribution of different particles to the total energy deposition in lead target by CEM2K-Cascade-Mode

    粒子800 MeV1000 MeV1200 MeV
    沉积能
    量/MeV
    对总能量沉积值
    的占比/%
    沉积能
    量/MeV
    对总能量沉积值
    的占比/%
    沉积能
    量/MeV
    对总能量沉积值
    的占比/%
    全部粒子497.9100572.0100648.7100
    质子413.983.13435.676.15455.070.15
    光子47.59.5474.813.08104.016.03
    π00.20.040.40.060.50.08
    带电π介子(± π)6.61.3313.72.3921.93.37
    13.72.7521.23.7129.04.47
    5.01.018.51.4812.31.90
    氦–32.80.575.10.908.01.23
    α粒子6.11.2310.11.7714.62.26
    中子2.00.402.70.473.30.51
    初级质子
    电离作用
    268.852.73247.948.63233.145.72
    DownLoad: CSV

    表 2  BERTINI, ISABEL, CEM2K与INCL4级联模型计算1000 MeV质子入射铅靶产生的不同粒子对总能量沉积值的占比贡献

    Table 2.  The calculated contribution of different particles to the total energy deposition in lead target by 1000 MeV protons with BERTINI, ISABEL, CEM2K, and INCL4 cascade mode.

    粒子BERTINIISABELCEM2 KINCL4
    沉积能
    量/MeV
    对总能量沉积值
    的占比/%
    沉积能
    量/MeV
    对总能量沉积值
    的占比/%
    沉积能
    量/MeV
    对总能量沉积值
    的占比/%
    沉积能
    量/MeV
    对总能量沉积值
    的占比/%
    全部粒子580.3100603.0100572.0100.00594.5100
    质子474.081.67493.081.76435.676.15500.684.20
    光子63.710.9876.212.6474.813.0860.710.21
    π00.30.050.30.050.30.060.30.04
    带电π介
    子(± π)
    14.92.5613.92.3113.72.3915.52.60
    6.41.103.70.6221.23.714.00.67
    3.00.521.90.328.51.481.80.30
    氦–30.40.060.10.025.10.900.20.03
    α粒子14.82.5611.81.9610.11.779.11.53
    中子2.90.491.90.322.70.472.50.42
    初级质子电
    离作用
    245.148.06243.647.79247.948.63245.048.06
    DownLoad: CSV
  • [1]

    Wang F W, Liang T J, Yin W, Yu Q Z, He L H, Tao J Z, Zhu T, Jia X J, Zhang S Y 2013 Sci. China Phys. Mech. Astron. 56 2410Google Scholar

    [2]

    詹文龙, 徐瑚珊 2012 中国科学院院刊 27 375Google Scholar

    Zhan W L, Xu H S 2012 Bul. Ch. Acad. Sci. 27 375Google Scholar

    [3]

    于全芝, 殷雯, 梁天骄 2011 物理学报 60 052501Google Scholar

    Yu Q Z, Yin W, Liang T J 2011 Acta Phys. Sin. 60 052501Google Scholar

    [4]

    Pelowitz D B 2005 MCNPX User’s Manual version 2.5.0 (Los Alamos: Los Alamos National Laboratory)

    [5]

    Tatsuhiko S, Koji N, Norihiro M, Shintaro H, Yosuke I, Shusaku N, Tatsuhiko O, Hiroshi I, Hiroshi N, Tokio F, Keisuke O, Tetsuya K, Satoshi C 2013 J. Nucl. Sci. Technol. 50 913Google Scholar

    [6]

    Alfredo F, Paola R S, Alberto F, Johannes R FLUKA: A Multi-particle Transport Code (Italian National Institute for Nuclear Physics (INFN) and European Organization for Nuclear Research (CERN))

    [7]

    Belyakov-Bodin V I, Kazaritsky V D, Povarov A L, Chuvilo I V, Sherstnev V A 1990 Nucl. Instr. Meth. A 295 140Google Scholar

    [8]

    Belyakov-Bodin V I, Andreev A M, Dubinsky V D, Kazaritsky V D, Povarov A L, Chuvilo I V, Sherstnev V A 1992 Nucl. Instr. Meth. A 314 508Google Scholar

    [9]

    Belyakov-Bodin V I, Andreev A M, Dubinsky V D, Chuvilo I V, Sherstnev V A 1993 Nucl. Instr. Meth. A 335 30Google Scholar

    [10]

    Belyakov-Bodin V I, Azhgirey I L, Degtyarev I I 2007 Nucl. Instr. Meth. A 572 935Google Scholar

    [11]

    Bauer G S, Spitzer H, Holzen G V, Ni L, Hastings J 1998 14th Meeting of the Int. Collaboration on Advanced Neutron Sources, Uitica I L USA, June 14–19, 1998 p229

    [12]

    Filges D, Neef R D, Schaal H 1998 Proc. of the Fourth Workshop on Simulating Accelerator Radiation Environments, Konxville TN USA, September 14–16, 1998 p221

    [13]

    Tietze A 2001 Ph. D. Dissertation (Wuppertal: University of Wuppertal)

    [14]

    Xia J W, Zhan W L, Wei B W, Yuan Y J, Song M T, Zhang W Z, Yang X D, Yuan P, Gao D Q, Zhao H W, Yang X T, Xiao G Q, Man K T, Dang J R, Cai X H, Wang Y F, Tang J Y, Qiao W M, Rao Y N, He Y, Mao L Z, Zhou Z Z 2002 Nucl. Instr. Meth. A 488 11Google Scholar

    [15]

    Detlef F, Frank G 2009 Handbook of Spallation Research: Theory, Experiments and Applications (Weinheim: WILEY-VCH)

    [16]

    奥伯霍弗, 沙尔曼著 (张彤译) 1988 应用热释光剂量学(北京: 中国计量出版社)

    Oberhofer M, Scharmann A (translated by Zhang T) 1988 The Applied Thermoluminescence Dosimetry (Beijing: China Metrology Press)(in Chinese)

    [17]

    赵建兴, 王峰, 唐开勇, 李海俊, 刘大海, 肖无云, 崔辉 2011 核技术 34 103

    Zhao J X, Wang F, Tang K Y, Li H J, Liu D H, Xiao W Y, Cui H 2011 J. Nucl. Tech. 34 103

    [18]

    Massillon-JL G, Gamboa-deBuen I, Brandan M E 2007 J. Phys. D: Appl. Phys. 40 2584Google Scholar

    [19]

    Bilski P, Berger T, Hajek M, Reitz G 2011 Radi Meas. 46 1728Google Scholar

    [20]

    James F Z, http://www.srim.org [2009]

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Publishing process
  • Received Date:  09 September 2020
  • Accepted Date:  27 October 2020
  • Available Online:  21 February 2021
  • Published Online:  05 March 2021

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