Conception design of helium ion FFAG accelerator with induction accelerating cavity

LUO Huan-Li; XU Yu-Cun; WANG Xiang-Qi; XU Hong-Liang

doi:10.1088/1674-1137/37/9/097001

Chinese Physics C> 2013, Vol. 37> Issue(9) : 097001 DOI: 10.1088/1674-1137/37/9/097001

Conception design of helium ion FFAG accelerator with induction accelerating cavity

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In the recent decades of particle accelerator R&D area, the fixed field alternating gradient (FFAG) accelerator has become a highlight for some advantages of its higher beam intensity and lower cost, although there are still some technical challenges. In this paper, the FFAG accelerator is adopted to accelerate a helium ion beam on the one hand for the study of helium embrittlement on fusion reactor envelope material and on the other hand for promoting the conception research and design of the FFAG accelerator and exploring the possibility of developing high power FFAG accelerators. The conventional period focusing unit of the helium ion FFAG accelerator and three-dimensional model of the large aperture combinatorial magnet by OPERA-TOSCA are given. For low energy and low revolution frequency, induction acceleration is proposed to replace conventional radio frequency (RF) acceleration for the helium ion FFAG accelerator, which avoids the potential breakdown of the acceleration field caused by the wake field and improves the acceleration repetition frequency to gain higher beam intensity. The main parameters and three-dimensional model of induction cavity are given. Two special constraint waveforms are proposed to refrain from particle accelerating time slip (ΔT) caused by accelerating voltage drop of flat top and energy deviation. The particle longitudinal motion in two waveforms is simulated.

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[1]

Kaichiro Mishima, Hironobu Unesaki, Tsuyoshi Misawa et al. Nuclear Science and Technology, 2007, 44(3): 499-503[2] Cheol Ho Pyeon, Morgan Hervault, Tsuyoshi Misawa et al. Nuclear Science and Technology, 2008, 45(11): 1171-1182[3] Tanigaki M, Takamiya K, Yoshino H et al. Nuclear Instruments and Methods in Physics Research A, 2010, 612: 354-359[4] Koji Yoshimura. Nuclear Instruments and Methods in Physics Research A, 2003, 503: 254-257[5] Meot F. Nuclear Physics B (Proc. Suppl.), 2006, 155: 79-83[6] Geer S, Zisman M S. Progress in Particle and Nuclear Physics, 2007, 59: 631-693[7] Muramatsu M, Kitagawa A, Sato Y et al. Review of Scientific Instruments, 2002, 73(2): 573-575[8] Trbojevic D, Parker B. Physical Review Special Topics-Accelerators and Beams, 2007, 10: 053503[9] Keil E, Sessler A M, Trbojevic D. Physical Review Special Topics-Accelerators and Beams, 2007, 10: 054701[10] ZHANG Chong-Hong, CHEN Ke-Qin, WANG Yin-Shu et al. Nuclear Physics Review, 2001, 18(1): 50-55[11] Kramer D, Brager H R, Rhodes C G et al. Journal of Nuclear Materials, 1968, 25(2): 121-131[12] Ken Takayama, Junichi Kishiro. Nuclear Instruments and Methods in Physics Research A, 2000, 451: 304-317[13] TanujaS.Dixit, TaikiIwashita, KenTakayama. Nuclear Instruments and Methods in Physics Research A, 2009, 602: 326-336[14] Cunningham G S, Morris C. Los Alamos Science, 2003, 28: 76-91[15] SONG Zhi-Zhong, YU Jin-Xiang, GUO Zhi-Yu et al. Nuclear Techniques, 2006, 29(2): 90-92

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LUO Huan-Li, XU Yu-Cun, WANG Xiang-Qi and XU Hong-Liang. Conception design of helium ion FFAG accelerator with induction accelerating cavity[J]. Chinese Physics C, 2013, 37(9): 097001. doi: 10.1088/1674-1137/37/9/097001

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Received: 2012-10-15
Revised: 1900-01-01

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通讯作者: 陈斌, bchen63@163.com

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沈阳化工大学材料科学与工程学院沈阳 110142

Conception design of helium ion FFAG accelerator with induction accelerating cavity

Corresponding author: LUO Huan-Li,

Corresponding author: WANG Xiang-Qi,

Received Date: 2012-10-15

Accepted Date: 1900-01-01

Available Online: 2013-09-05

Abstract: In the recent decades of particle accelerator R&D area, the fixed field alternating gradient (FFAG) accelerator has become a highlight for some advantages of its higher beam intensity and lower cost, although there are still some technical challenges. In this paper, the FFAG accelerator is adopted to accelerate a helium ion beam on the one hand for the study of helium embrittlement on fusion reactor envelope material and on the other hand for promoting the conception research and design of the FFAG accelerator and exploring the possibility of developing high power FFAG accelerators. The conventional period focusing unit of the helium ion FFAG accelerator and three-dimensional model of the large aperture combinatorial magnet by OPERA-TOSCA are given. For low energy and low revolution frequency, induction acceleration is proposed to replace conventional radio frequency (RF) acceleration for the helium ion FFAG accelerator, which avoids the potential breakdown of the acceleration field caused by the wake field and improves the acceleration repetition frequency to gain higher beam intensity. The main parameters and three-dimensional model of induction cavity are given. Two special constraint waveforms are proposed to refrain from particle accelerating time slip (ΔT) caused by accelerating voltage drop of flat top and energy deviation. The particle longitudinal motion in two waveforms is simulated.

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Conception design of helium ion FFAG accelerator with induction accelerating cavity

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