Relationship of mode transitions and standing waves in helicon plasmas

被引:0
|
作者
吴明阳 [1 ]
肖池阶 [1 ]
王晓钢 [1 ,2 ]
刘悦 [3 ]
许敏 [4 ]
谭畅 [5 ,6 ]
徐田超 [1 ]
余修铭 [1 ]
何任川 [1 ]
许安冬 [1 ]
机构
[1] State Key Laboratory of Nuclear Physics and Technology School of Physics Fusion Simulation CenterPeking University
[2] Department of Physics Institute of Space Environment and Matter Science Harbin Institute of Technology
[3] Key Laboratory of Materials Modification by Laser Ion and Electron Beams (Ministry of Education)School of Physics Dalian University of Technology
[4] Center for Fusion Science of Southwestern Institute of Physics
[5] Shaanxi Key Laboratory of Plasma Physics and Applied Technology
[6] Xi’an Aerospace Propulsion
来源
Plasma Science and Technology | 2022年 / 05期
关键词
D O I
暂无
中图分类号
O53 [等离子体物理学];
学科分类号
070204 ;
摘要
Helicon wave plasma sources have the well-known advantages of high efficiency and high plasma density, with broad applications in many areas. The crucial mechanism lies with mode transitions, which has been an outstanding issue for years. We have built a fluid simulation model and further developed the Peking University Helicon Discharge code. The mode transitions, also known as density jumps, of a single-loop antenna discharge are reproduced in simulations for the first time. It is found that large-amplitude standing helicon waves(SHWs) are responsible for the mode transitions, similar to those of a resonant cavity for laser generation.This paper intends to give a complete and quantitative SHW resonance theory to explain the relationship of the mode transitions and the SHWs. The SHW resonance theory reasonably explains several key questions in helicon plasmas, such as mode transition and efficient power absorption, and helps to improve future plasma generation methods.
引用
收藏
页码:92 / 98
页数:7
相关论文
共 50 条
  • [1] Relationship of mode transitions and standing waves in helicon plasmas
    Wu, Mingyang
    Xiao, Chijie
    Wang, Xiaogang
    Liu, Yue
    Xu, Min
    Tan, Chang
    Xu, Tianchao
    Yu, Xiuming
    He, Renchuan
    Xu, Andong
    PLASMA SCIENCE & TECHNOLOGY, 2022, 24 (05)
  • [2] Relationship of mode transitions and standing waves in helicon plasmas
    吴明阳
    肖池阶
    王晓钢
    刘悦
    许敏
    谭畅
    徐田超
    余修铭
    何任川
    许安冬
    Plasma Science and Technology, 2022, 24 (05) : 92 - 98
  • [3] Characteristics of plasmas excited by helicon waves
    Braginskii, OV
    Vasil'eva, AN
    Kovalev, AS
    PLASMA PHYSICS REPORTS, 1998, 24 (09) : 762 - 766
  • [4] Mode transitions in helicon discharges
    Franck, CM
    Grulke, O
    Klinger, T
    PHYSICS OF PLASMAS, 2003, 10 (01) : 323 - 325
  • [5] Theory of mode conversion in helicon plasmas
    Cho, Suwon
    PLASMA SOURCES SCIENCE & TECHNOLOGY, 2020, 29 (09):
  • [6] Plasma production by m = 0 standing helicon waves
    Nisoa, Mudtorlep
    Sakawa, Youichi
    Shoji, Tatsuo
    Japanese Journal of Applied Physics, Part 2: Letters, 2000, 39 (5 A):
  • [7] Plasma production by m=0 standing helicon waves
    Nisoa, M
    Sakawa, Y
    Shoji, T
    JAPANESE JOURNAL OF APPLIED PHYSICS PART 2-LETTERS & EXPRESS LETTERS, 2000, 39 (5A): : L429 - L432
  • [8] Standing Helicon Wave Induced by a Rapidly Bent Magnetic Field in Plasmas
    Takahashi, Kazunori
    Takayama, Sho
    Komuro, Atsushi
    Ando, Akira
    PHYSICAL REVIEW LETTERS, 2016, 116 (13)
  • [9] Nonlinear standing waves in bounded plasmas
    Amiranashvili, S
    Yu, MY
    Stenflo, L
    Brodin, G
    Servin, M
    PHYSICAL REVIEW E, 2002, 66 (04): : 6 - 046403
  • [10] Landau and collisional damping induced power deposition for the m=0 mode of helicon and Trivelpiece-Gould waves in high density helicon plasmas
    Li, Wenqiu
    Zhao, Bin
    Wang, Gang
    Xiang, Dong
    AIP ADVANCES, 2020, 10 (08)
12345