Optimization of an m = 0 multi-loop helicon source configuration for linear plasma devices: A comparative study with Boswell and half-helix antenna designs

doi:10.1088/1674-1056/ade24b

中国物理B ›› 2025, Vol. 34 ›› Issue (12): 125202-125202.doi: 10.1088/1674-1056/ade24b

Optimization of an m = 0 multi-loop helicon source configuration for linear plasma devices: A comparative study with Boswell and half-helix antenna designs

Yi Yu(余羿)^1,†, Hao Liu(刘灏)^2,‡, Xue-Dong Huang(黄学栋)¹, Chen-Yu Xiao(肖晨雨)¹, Lin Nie(聂林)², Guang-Yi Zhao(赵光义)², and Min Xu(许敏)²

1 Sino-French Institute of Nuclear Engineering and Technology, Sun Yat-sen University, Zhuhai 519082, China 2 Southwestern Institute of Physics, Chengdu 610041, China

收稿日期:2025-03-28 修回日期:2025-05-28 接受日期:2025-06-09 发布日期:2025-12-15
通讯作者: Yi Yu, Hao Liu E-mail:yuyi56@mail.sysu.edu.cn;liuhao@swip.ac.cn
基金资助:
Project supported by the National Key Research and Development Program of China (Grant No. 2022YFE03100002) and the National Natural Science Foundation of China (Grant Nos. 12435015 and 12075241).

Optimization of an m = 0 multi-loop helicon source configuration for linear plasma devices: A comparative study with Boswell and half-helix antenna designs

Yi Yu(余羿)^1,†, Hao Liu(刘灏)^2,‡, Xue-Dong Huang(黄学栋)¹, Chen-Yu Xiao(肖晨雨)¹, Lin Nie(聂林)², Guang-Yi Zhao(赵光义)², and Min Xu(许敏)²

1 Sino-French Institute of Nuclear Engineering and Technology, Sun Yat-sen University, Zhuhai 519082, China 2 Southwestern Institute of Physics, Chengdu 610041, China

Received:2025-03-28 Revised:2025-05-28 Accepted:2025-06-09 Published:2025-12-15
Contact: Yi Yu, Hao Liu E-mail:yuyi56@mail.sysu.edu.cn;liuhao@swip.ac.cn
Supported by:
Project supported by the National Key Research and Development Program of China (Grant No. 2022YFE03100002) and the National Natural Science Foundation of China (Grant Nos. 12435015 and 12075241).

摘要/Abstract

摘要： This article presents the physics for determining an appropriate helicon plasma source for the linear experimental advanced device (LEAD) through tripartite mutual verification encompassing theoretical analysis, code simulation, and experimental validation. Using the HELIC code, plasma excitation processes were simulated with three antenna configurations: $m =1 $ half-helix, $m =1 $ Boswell, and $m =0 $ single-loop helicon antennas, and complemented by theoretical analysis. Key parameters including plasma impedance ($R_{\rm p}$) and energy deposition profiles along radial ($P_{r}$) and axial ($P_{z}$) directions were comparatively analyzed, revealing significantly enhanced $R_{\rm p}$, $P_{r}$, and $P_{z}$ values for the loop antenna configuration as compared with other configurations. Wave propagation equation solutions predicted a primary plasma generation layer at the antenna center; numerical simulations identified an additional plasma formation region at the antenna boundary, indicative of edge Landau damping effects. Interestingly, stronger axial magnetic fields do not necessarily result in higher plasma densities, especially for $m =0 $ antenna configurations. Experimental validation conducted with an $m =0 $ multi-loop plasma source confirmed these findings. Both theoretical analyses and experimental studies on large-volume plasma generation utilizing this innovative source elucidated the underlying mechanisms responsible for the remarkable low mode transition threshold of 150-watt input power and demonstrated significantly enhanced plasma confinement properties.

关键词: multi-loop helicon source, m=0 helicon source, linear plasma device

Abstract: This article presents the physics for determining an appropriate helicon plasma source for the linear experimental advanced device (LEAD) through tripartite mutual verification encompassing theoretical analysis, code simulation, and experimental validation. Using the HELIC code, plasma excitation processes were simulated with three antenna configurations: $m =1 $ half-helix, $m =1 $ Boswell, and $m =0 $ single-loop helicon antennas, and complemented by theoretical analysis. Key parameters including plasma impedance ($R_{\rm p}$) and energy deposition profiles along radial ($P_{r}$) and axial ($P_{z}$) directions were comparatively analyzed, revealing significantly enhanced $R_{\rm p}$, $P_{r}$, and $P_{z}$ values for the loop antenna configuration as compared with other configurations. Wave propagation equation solutions predicted a primary plasma generation layer at the antenna center; numerical simulations identified an additional plasma formation region at the antenna boundary, indicative of edge Landau damping effects. Interestingly, stronger axial magnetic fields do not necessarily result in higher plasma densities, especially for $m =0 $ antenna configurations. Experimental validation conducted with an $m =0 $ multi-loop plasma source confirmed these findings. Both theoretical analyses and experimental studies on large-volume plasma generation utilizing this innovative source elucidated the underlying mechanisms responsible for the remarkable low mode transition threshold of 150-watt input power and demonstrated significantly enhanced plasma confinement properties.

Key words: multi-loop helicon source, m=0 helicon source, linear plasma device

中图分类号: (Plasma sources)

52.50.Dg

52.50.Qt (Plasma heating by radio-frequency fields; ICR, ICP, helicons) 52.75.-d (Plasma devices)

Yi Yu(余羿), Hao Liu(刘灏), Xue-Dong Huang(黄学栋), Chen-Yu Xiao(肖晨雨), Lin Nie(聂林), Guang-Yi Zhao(赵光义), and Min Xu(许敏). Optimization of an m = 0 multi-loop helicon source configuration for linear plasma devices: A comparative study with Boswell and half-helix antenna designs[J]. 中国物理B, 2025, 34(12): 125202-125202.

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Optimization of an m = 0 multi-loop helicon source configuration for linear plasma devices: A comparative study with Boswell and half-helix antenna designs

Optimization of an m = 0 multi-loop helicon source configuration for linear plasma devices: A comparative study with Boswell and half-helix antenna designs

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