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螺旋波等离子体中螺旋波与Trivelpiece-Gould波模式耦合及线性能量沉积特性参量分析

李文秋 赵斌 王刚 相东

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螺旋波等离子体中螺旋波与Trivelpiece-Gould波模式耦合及线性能量沉积特性参量分析

李文秋, 赵斌, 王刚, 相东

Parametric analysis of mode coupling and liner energy deposition properties of helicon and Trivelpiece-Gould waves in helicon plasma

Li Wen-Qiu, Zhao Bin, Wang Gang, Xiang Dong
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  • 采用有限温度等离子体介电张量模型, 在考虑粒子热效应情形下, 通过求解传导边界条件下等离子体柱中本征模的色散关系, 分析了螺旋波等离子体中典型参量条件下螺旋波与Trivelpiece-Gould (TG) 波的耦合特性及线性能量沉积特性. 在ω/(2π) = 13.56 MHz和TeV,i = 0.1TeV,e参量条件下计算结果表明: 对于螺旋波, 存在截止静磁场B0,H,cutoff与截止等离子体密度n0,H,cutoff, 在B0 > B0,H,cutoffn0 < n0,H,cutoff条件下, 螺旋波变为消逝波; 在ω/ωce ∈ (0.01, 0.10)范围内, 对于m = 0 角向模, TG波Landau阻尼致使的能量沉积占主导地位, 而对于m = 1角向模, 螺旋波Landau阻尼或TG波Landau阻尼致使的能量沉积哪个占据主导地位则取决于B0的大小; 在ωpe/ωce ∈ (3, 100)范围内, TG波Landau阻尼致使的能量沉积占主导地位; 在整体能量沉积过程中, 对于m = 0模和m = 1模, Landau阻尼致使的能量沉积均占据主导地位.
    Based on the finite temperature plasma dielectric tensor model which contains the particle thermal effect, by numerically solving the eigenmode dispersion relation of electromagnetic waves propagating in radially uniform and magnetized warm plasma column which is surrounded by conducting boundary, the mode coupling characteristic and liner damping mechanism induced wave power deposition properties of helicon and Trivelpiece-Gould (TG) waves are parametrically analyzed. The detailed investigations show as follows. Under typical helicon plasma parameter conditions, i.e. wave frequency ω/(2π) = 13.56 MHz, ion temperature is much smaller than electron temperature, for the helicon wave, there exist a cut-off magnetic field B0,H,cutoff and a cut-off plasma density n0,H,cutoff, for which under the conditions of B0 > B0,H,cutoff or n0 < n0,H,cutoff, the helicon wave becomes an evanescent wave. When the magnetic field intensity changes from 48.4 to 484 G, i.e., ω/ωce ranges from 0.01 to 0.1, for the power deposition intensity, Landau damping of TG wave dominates for the m = 0 mode, meanwhile, for the m = 1 mode, which wave, i.e. helicon wave or TG wave, plays a major role in power deposition mainly depends on the magnitude of the magnetic field. On the other hand, for a given magnetic field B0 = 100 G, when ωpe/ωce changes from 3 to 100, for both the m = 0 mode and the m = 1 mode, the power deposition induced by Landau damping of TG wave plays a major role, further, one may notice that the power deposition of TG wave decreases while the power deposition of the helicon wave increases as plasma density increases. Finally, for both the m = 0 mode and the m = 1 mode, the power deposition due to the Landau damping plays a dominant role. All these conclusions provide us with some useful clues to better understanding the high ionization mechanism of helicon wave discharges.
      通信作者: 李文秋, beiste@163.com
    • 基金项目: 国家级-国家“万人计划”科技创新领军人才(Y8BF130272)
      Corresponding author: Li Wen-Qiu, beiste@163.com
    [1]

    Chen F F 2015 Plasma Sources Sci. Technol. 24 014001Google Scholar

    [2]

    Isayama S, Shinohara S, Hada T 2018 Plasma Fusion Res. 13 1101014Google Scholar

    [3]

    Shinohara S 2018 Adv. Phys.: X 3 1420424Google Scholar

    [4]

    Aigrain P 1960 Proceedings of the International Conference on Semiconductor Physics Prague, Czech Republic, August 4–8, 1960 p224

    [5]

    Chen F F 1991 Plasma Phys. Controlled Fusion 33 339Google Scholar

    [6]

    Shamrai K P, Taranov V B 1996 Plasma Sources Sci. Technol. 5 474Google Scholar

    [7]

    Shamrai K P, Taranov V B 1994 Plasma Phys. Controlled Fusion 36 1719Google Scholar

    [8]

    Shamrai K P 1998 Plasma Sources Sci. Technol. 7 499Google Scholar

    [9]

    Chen F F, Blackwell D D 1999 Phys. Rev. Lett. 82 2677Google Scholar

    [10]

    Blackwell D D, Chen F F 2001 Plasma Sources Sci. Technol. 10 226Google Scholar

    [11]

    Kline J, Scime E 2003 Phys. Plasmas 10 135Google Scholar

    [12]

    Kim S, Hwang Y 2008 Plasma Phys. Controlled Fusion 50 035007Google Scholar

    [13]

    Isayama S, Hada T, Shinohara S, et al. 2016 Phys. Plasmas 23 063513Google Scholar

    [14]

    成玉国, 程谋森, 王墨戈等 2014 物理学报 63 035203Google Scholar

    Cheng Y G, Cheng M S, Wang M G, et al. 2014 Acta Phys. Sin. 63 035203Google Scholar

    [15]

    平兰兰, 张新军, 杨桦等 2019 物理学报 68 205201Google Scholar

    Ping L L, Zhang X J, Yang H, et al. 2019 Acta Phys.Sin. 68 205201Google Scholar

    [16]

    Chen F F, Arnush D 1997 Phys. Plasmas 4 3411Google Scholar

    [17]

    Arnush D, Chen F F 1998 Phys. Plasmas 5 1239Google Scholar

    [18]

    Arnush D 2000 Phys. Plasmas 7 3042Google Scholar

    [19]

    Sakawa Y, Kunimatsu H, Kikuchi H, et al. 2003 Phys. Rev. Lett. 90 105001Google Scholar

    [20]

    Vey B 1984 PFC/RR-84-12 (Cambridge: Massachusetts Institute of Technology) pp30–31

    [21]

    Niemi K, Krämer M 2008 Phys. Plasmas 15 073503Google Scholar

    [22]

    Shamrai K P, Shinohara S 2001 Phys. Plasmas 8 4659Google Scholar

    [23]

    Huba J D 2016 NRL Plasma Formulary (Washington: Naval Research Laboratory) p34

    [24]

    Fried B D, Conte S D 2015 The Plasma Dispersion Function: the Hilbert Transform of the Gaussian (New York: Academic Press) pp1–3

    [25]

    Mouzouris Y, Scharer J E 1998 Phys. Plasmas 5 4253Google Scholar

    [26]

    Shoji T, Sakawa Y, Nakazawa S, et al. 1993 Plasma Sources Sci. Technol. 2 5Google Scholar

    [27]

    Swanson D G 1989 Plasma Waves (New York: Academic Press) pp375–376

    [28]

    Lafleur T, Charles C, Boswell R 2010 Phys. Plasmas 17 073508Google Scholar

  • 图 1  被传导边界包裹的等离子体柱横向截面示意图

    Fig. 1.  Cross section of plasma column surround by conducting boundary

    图 2  粒子温度对螺旋波与TG波耦合色散关系的影响 (a)电子温度的影响; (b)离子温度的影响

    Fig. 2.  Influence of particle temperature on dispersion relation between helicon and TG waves: (a) Electron temperature effect; (b) ion temperature effect.

    图 3  螺旋波与TG波横向波数对轴向静磁场的依赖关系

    Fig. 3.  The perpendicular wave number of helicon and TG waves given as functions of axial static magnetic field.

    图 4  螺旋波与TG波横向波数对等离子体密度的依赖关系

    Fig. 4.  The perpendicular wave number of helicon and TG waves given as functions of plasma density.

    图 5  螺旋波轴向波数随参量变化情况 (a)轴向波数随轴向静磁场变化; (b)轴向静磁场随等离子体密度变化

    Fig. 5.  The axial wave number of the right hand polarized wave is given as a function of (a) axial static magnetic field and (b) plasma density.

    图 6  螺旋波与TG波径向功率沉积分布 (a) m = 0 角向对称模; (b) m = 1 角向对称模

    Fig. 6.  Radial power deposition profiles of the helicon and TG waves for: (a) m = 0 mode; (b) m = 1 mode.

    图 7  螺旋波与TG波功率沉积随电子温度的变化关系 (a) m = 0 模; (b) m = 1 模

    Fig. 7.  Power deposition profiles of helicon and TG waves are given as functions of electron temperature for: (a) m = 0 mode; (b) m = 1 mode.

    图 8  螺旋波与TG波功率沉积随离子温度的变化关系 (a) m = 0 模; (b) m = 1 模

    Fig. 8.  Power deposition profiles of helicon and TG waves are given as functions of ion temperature for: (a) m = 0 mode; (b) m = 1 mode.

    图 9  螺旋波与TG波功率沉积随轴向静磁场的变化关系 (a) m = 0 模; (b) m = 1 模

    Fig. 9.  Power deposition profiles of helicon and TG waves are given as functions of axial static magnetic field for: (a) m = 0 mode; (b) m = 1 mode.

    图 10  螺旋波与TG波功率沉积随等离子体密度的变化关系 (a) m = 0 模; (b) m = 1 模

    Fig. 10.  Power deposition profiles of helicon and TG waves are given as functions of plasma density for: (a) m = 0 mode; (b) m = 1 mode.

  • [1]

    Chen F F 2015 Plasma Sources Sci. Technol. 24 014001Google Scholar

    [2]

    Isayama S, Shinohara S, Hada T 2018 Plasma Fusion Res. 13 1101014Google Scholar

    [3]

    Shinohara S 2018 Adv. Phys.: X 3 1420424Google Scholar

    [4]

    Aigrain P 1960 Proceedings of the International Conference on Semiconductor Physics Prague, Czech Republic, August 4–8, 1960 p224

    [5]

    Chen F F 1991 Plasma Phys. Controlled Fusion 33 339Google Scholar

    [6]

    Shamrai K P, Taranov V B 1996 Plasma Sources Sci. Technol. 5 474Google Scholar

    [7]

    Shamrai K P, Taranov V B 1994 Plasma Phys. Controlled Fusion 36 1719Google Scholar

    [8]

    Shamrai K P 1998 Plasma Sources Sci. Technol. 7 499Google Scholar

    [9]

    Chen F F, Blackwell D D 1999 Phys. Rev. Lett. 82 2677Google Scholar

    [10]

    Blackwell D D, Chen F F 2001 Plasma Sources Sci. Technol. 10 226Google Scholar

    [11]

    Kline J, Scime E 2003 Phys. Plasmas 10 135Google Scholar

    [12]

    Kim S, Hwang Y 2008 Plasma Phys. Controlled Fusion 50 035007Google Scholar

    [13]

    Isayama S, Hada T, Shinohara S, et al. 2016 Phys. Plasmas 23 063513Google Scholar

    [14]

    成玉国, 程谋森, 王墨戈等 2014 物理学报 63 035203Google Scholar

    Cheng Y G, Cheng M S, Wang M G, et al. 2014 Acta Phys. Sin. 63 035203Google Scholar

    [15]

    平兰兰, 张新军, 杨桦等 2019 物理学报 68 205201Google Scholar

    Ping L L, Zhang X J, Yang H, et al. 2019 Acta Phys.Sin. 68 205201Google Scholar

    [16]

    Chen F F, Arnush D 1997 Phys. Plasmas 4 3411Google Scholar

    [17]

    Arnush D, Chen F F 1998 Phys. Plasmas 5 1239Google Scholar

    [18]

    Arnush D 2000 Phys. Plasmas 7 3042Google Scholar

    [19]

    Sakawa Y, Kunimatsu H, Kikuchi H, et al. 2003 Phys. Rev. Lett. 90 105001Google Scholar

    [20]

    Vey B 1984 PFC/RR-84-12 (Cambridge: Massachusetts Institute of Technology) pp30–31

    [21]

    Niemi K, Krämer M 2008 Phys. Plasmas 15 073503Google Scholar

    [22]

    Shamrai K P, Shinohara S 2001 Phys. Plasmas 8 4659Google Scholar

    [23]

    Huba J D 2016 NRL Plasma Formulary (Washington: Naval Research Laboratory) p34

    [24]

    Fried B D, Conte S D 2015 The Plasma Dispersion Function: the Hilbert Transform of the Gaussian (New York: Academic Press) pp1–3

    [25]

    Mouzouris Y, Scharer J E 1998 Phys. Plasmas 5 4253Google Scholar

    [26]

    Shoji T, Sakawa Y, Nakazawa S, et al. 1993 Plasma Sources Sci. Technol. 2 5Google Scholar

    [27]

    Swanson D G 1989 Plasma Waves (New York: Academic Press) pp375–376

    [28]

    Lafleur T, Charles C, Boswell R 2010 Phys. Plasmas 17 073508Google Scholar

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  • 收稿日期:  2020-01-09
  • 修回日期:  2020-03-31
  • 刊出日期:  2020-06-05

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