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《中国物理C》(英文)编辑部
2024年10月30日

Beam distribution reconstruction simulation for electron beam probe

  • An electron beam probe (EBP) is a detector which makes use of a low-intensity and low-energy electron beam to measure the transverse profile, bunch shape, beam neutralization and beam wake field of an intense beam with small dimensions. While it can be applied to many aspects, we limit our analysis to beam distribution reconstruction. This kind of detector is almost non-interceptive for all of the beam and does not disturb the machine environment. In this paper, we present the theoretical aspects behind this technique for beam distribution measurement and some simulation results of the detector involved. First, a method to obtain a parallel electron beam is introduced and a simulation code is developed. An EBP as a profile monitor for dense beams is then simulated using the fast scan method for various target beam profiles, including KV distribution, waterbag distribution, parabolic distribution, Gaussian distribution and halo distribution. Profile reconstruction from the deflected electron beam trajectory is implemented and compared with the actual profile, and the expected agreement is achieved. Furthermore, as well as fast scan, a slow scan, i.e. step-by-step scan, is considered, which lowers the requirement for hardware, i.e. Radio Frequency deflector. We calculate the three-dimensional electric field of a Gaussian distribution and simulate the electron motion in this field. In addition, a fast scan along the target beam direction and slow scan across the beam are also presented, and can provide a measurement of longitudinal distribution as well as transverse profile simultaneously. As an example, simulation results for the China Accelerator Driven Sub-critical System (CADS) and High Intensity Heavy Ion Accelerator Facility (HIAF) are given. Finally, a potential system design for an EBP is described.
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    [8] W. Blokland, S. Cousineau, A Non-Destructive Profile Monitor for High Intensity Beams, in Proceedings of 2011 Particle Accelerator Conference (PAC), p.1438
    [9] R. M. Thurman-Keup, M. L. Alvarez, J. Fitzgerald et al, Electron Beam Profiler for the Fermilab Main Injector, in Proceedings of the 3rd International Beam Instrumentation Conference (IBIC), p.398
    [10] R. M. Thurman-Keup, M. L. Alvarez, J. Fitzgerald et al, Installation Status of the Electron Beam Profiler for the Fermilab Main Injector, in Proceedings of the 4rd International Beam Instrumentation Conference (IBIC), p.535
    [11] P. V. Logatchov, P. A. Bak, A. A. Starostenko et al, Non-Destructive Singlepass Monitor of Longitudinal Charge Distribution in An Ultrarelativistic Electron Bunch, in Proceedings of the 1999 Particle Accelerator Conference (PAC), p.2167
    [12] A. A. Starostenko, P. A. Bak, Y. A. Gusev et al, Nnon-Destructive Singlepass Bunch Length Monitor: Experiments at VEPP-5 Preinjector Electron Linac, in Proceedings of the seventh European Particle Accelerator Conference (EPAC), p.1720
    [13] P. V. Logachev, D. A. Malyutin, A. A. Starostenko, Instruments and Experimental Techniques, 51(1): 1-27 (2008)
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    [19] A. Aleksandrov, S. Assadi, S. Cousineau et al, Feasibility Study of Using an Electron Beam For Profile Measurements in the SNS Accumulator Ring, in Proceedings of 2005 Particle Accelerator Conference (PAC), p.2586
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Yong-Chun Feng, Rui-Shi Mao, Peng Li, Xin-Cai Kang, Yan Yin, Tong Liu, Yao-Yao You, Yu-Cong Chen, Tie-Cheng Zhao, Zhi-Guo Xu, Yan-Yu Wang and You-Jin Yuan. Beam distribution reconstruction simulation for electron beam probe[J]. Chinese Physics C, 2017, 41(7): 077001. doi: 10.1088/1674-1137/41/7/077001
Yong-Chun Feng, Rui-Shi Mao, Peng Li, Xin-Cai Kang, Yan Yin, Tong Liu, Yao-Yao You, Yu-Cong Chen, Tie-Cheng Zhao, Zhi-Guo Xu, Yan-Yu Wang and You-Jin Yuan. Beam distribution reconstruction simulation for electron beam probe[J]. Chinese Physics C, 2017, 41(7): 077001.  doi: 10.1088/1674-1137/41/7/077001 shu
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Received: 2016-12-29
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Beam distribution reconstruction simulation for electron beam probe

    Corresponding author: Rui-Shi Mao,
  • 1. Institute of Modern Physics, Chinese Academy of Sciences, Lanzhou 730000, China
  • 2. University of Chinese Academy of Sciences, Beijing 100049, China
  • 3.  Institute of Modern Physics, Chinese Academy of Sciences, Lanzhou 730000, China

Abstract: An electron beam probe (EBP) is a detector which makes use of a low-intensity and low-energy electron beam to measure the transverse profile, bunch shape, beam neutralization and beam wake field of an intense beam with small dimensions. While it can be applied to many aspects, we limit our analysis to beam distribution reconstruction. This kind of detector is almost non-interceptive for all of the beam and does not disturb the machine environment. In this paper, we present the theoretical aspects behind this technique for beam distribution measurement and some simulation results of the detector involved. First, a method to obtain a parallel electron beam is introduced and a simulation code is developed. An EBP as a profile monitor for dense beams is then simulated using the fast scan method for various target beam profiles, including KV distribution, waterbag distribution, parabolic distribution, Gaussian distribution and halo distribution. Profile reconstruction from the deflected electron beam trajectory is implemented and compared with the actual profile, and the expected agreement is achieved. Furthermore, as well as fast scan, a slow scan, i.e. step-by-step scan, is considered, which lowers the requirement for hardware, i.e. Radio Frequency deflector. We calculate the three-dimensional electric field of a Gaussian distribution and simulate the electron motion in this field. In addition, a fast scan along the target beam direction and slow scan across the beam are also presented, and can provide a measurement of longitudinal distribution as well as transverse profile simultaneously. As an example, simulation results for the China Accelerator Driven Sub-critical System (CADS) and High Intensity Heavy Ion Accelerator Facility (HIAF) are given. Finally, a potential system design for an EBP is described.

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