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等离子体对共振磁扰动的流体和动理学响应的模拟研究

周利娜 胡汉卿 刘钺强 段萍 陈龙 张瀚予

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等离子体对共振磁扰动的流体和动理学响应的模拟研究

周利娜, 胡汉卿, 刘钺强, 段萍, 陈龙, 张瀚予

Modelling study of fluid and kinetic responses of plasmas to resonant magnetic perturbation

Zhou Li-Na, Hu Han-Qing, Liu Yue-Qiang, Duan Ping, Chen Long, Zhang Han-Yu
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  • 本文利用MARS-F/K程序和解析方法, 模拟研究了‘类-DEMO’平衡下等离子体对共振磁扰动的流体响应和动理学响应 . 研究发现, 当新的有理面经过等离子体边缘台基区时, 最外层有理面处总径向扰动场$ b_{{\text{res}}\left( {{\text{tot}}} \right)}^{\text{1}} $和等离子体边界X点附近扰动位移${\xi _X}$两个优化参数在特定的${q_{95}}$(95%归一化极向磁通量处的安全因子)窗口出现峰值, 峰值的个数y与环向模数n呈正相关, 即$y \approx n\Delta {q_{95}}$($\Delta {q_{95}} = 3.5$) . 上下两组线圈电流相位差的最优/差值与${q_{95}}$之间满足线性依赖关系, 可用线性函数进行拟合 . 线圈电流幅值的优化不改变电流相位差的最优值, 但可以增大优化参数${\xi _X}$ . 线圈电流幅值的最优值依赖于环向模数n . 包含背景粒子和高能粒子动理学效应的结果表明, 对于低$\beta $(等离子体比压值)等离子体, 动理学响应与流体响应保持一致, 与有无强平行声波阻尼无关; 而对于高$\beta $等离子体, 在流体响应模型中需要考虑动理学效应的修正作用 . 考虑强平行声波阻尼(${\kappa _\parallel } = 1.5$)的流体响应模型能够很好地预测‘类-DEMO’平衡的等离子体响应 .
    As is well known, large-scale type-I edge localized modes (ELMs) may pose serious risks to machine components in future large fusion devices. The resonant magnetic perturbation (RMP), generated by magnetic coils external to the plasma, can either suppress or mitigate ELMs, as has been shown in recent experiments on several present-day fusion devices. Understanding the ELM control with RMP may involve various physics. This work focuses on the understanding of the roles played by three key physical quantities: the edge safety factor, the RMP coil current, and the particle drift kinetic effects resulting from thermal and fusion-born α-particles. Full toroidal computations are performed by using the MARS-F/K codes. The results show that the plasma response based figures-of-merit i.e. the pitch resonant radial field component near the plasma edge and the plasma displacement near the X-point of the separatrix,consistently yield the same periodic amplification as $ q_{95} $ varies. The number of peaks, y, is positively correlated with the toroidal number n, i.e. $y \approx n\Delta {q_{95}}$ with $\Delta {q_{95}} = 3.5$. The peak window in $ q_{95} $ occurs when a new resonant surface passes through a specific region of the plasma edge. Two-dimensional parameter scans, for the edge safety factor and the coil phasing between the upper and lower rows of coils, yield a linear relationship between the optimal/worst current phase difference and $ q_{95} $, which can be well fitted by a simple analytic model. The optimal value of coil current amplitude is sensitive to n. Compared with the same current amplitude assumed for the two/three rows of coils, the optimal current amplitude can increase the ${\xi _{\text{X}}}$ but does not change the prediction of the relative toroidal phase difference. More advanced response model, including kinetic resonances between the RMP perturbation and drift motions of thermal particles and fusion-born alphas, shows that the modification of kinetic effects should be considered in order to better describe the plasma response to RMP fields in high-β plasmas. The fluid response model with a strong parallel sound wave damping (${\kappa _\parallel } = 1.5$) can well predict the plasma response for the ‘DEMO-like’ equilibria. For low β plasma, the kinetic response is consistent with the fluid response, whether a strong parallel sound wave damping exists or not.
      通信作者: 周利娜, zhoulina@dlmu.edu.cn ; 段萍, duanping@dlmu.edu.cn
    • 基金项目: 国家自然科学基金青年科学基金(批准号: 12205033)、国家自然科学基金(批准号: 11975062)、大连市中青年科技人才(批准号: 2022RQ039)和中央高校基本科研业务费专项资金(批准号: 3132022195)资助的课题.
      Corresponding author: Zhou Li-Na, zhoulina@dlmu.edu.cn ; Duan Ping, duanping@dlmu.edu.cn
    • Funds: Project supported by the Young Scientists Fund of the National Natural Science Foundation of China (Grant No. 12205033), the National Natural Science Foundation of China (Grant No. 11975062), Dalian Youth Science and Technology Project (Grant No. 2022RQ039), and the Fundamental Research Funds for the Central Universities (Grant No. 3132022195).
    [1]

    Suttrop W 2000 Plasma Phys. Contr. F. 42 A1Google Scholar

    [2]

    Loarte A, Lipschultz B, Kukushkin A S, Matthews G F, Stangeby P C, Asakura N, Counsell G F, Federici G, Kallenbach A, Krieger K, Mahdavi A, Philipps V, Reiter D, Roth J, Strachan J, Whyte D, Doerner R, Eich T, Fundamenski W, Herrmann A, Fenstermacher M, Ghendrih P, Groth M, Kirschner A, Konoshima S, LaBombard B, Lang P, Leonard A W, Monier-Garbet P, Neu R, Pacher H, Pegourie B, Pitts R A, Takamura S, Terry J, Tsitrone E, Group D P T 2007 Nucl. Fusion 47 S203Google Scholar

    [3]

    Ryter F, Fuchs J, Schneider W, Sips A, Stäbler A, Stober J, Team A U 2008 J. Phys. Conf. Ser. 123 012035Google Scholar

    [4]

    Loarte A, Saibene G, Sartori R, Becoulet M, Horton L, Eich T, Herrmann A, Laux M, Matthews G, Jachmich S, Asakura N, Chankin A, Leonard A, Porter G, Federici G, Shimada M, Sugihara M, Janeschitz G 2003 J. Nucl. Mater 313 962Google Scholar

    [5]

    Wenninger R P, Bernert M, Eich T, Fable E, Federici G, Kallenbach A, Loarte A, Lowry C, McDonald D, Neu R, Pütterich T, Schneider P, Sieglin B, Strohmayer G, Reimold F, Wischmeier M 2014 Nucl. Fusion 54 114003Google Scholar

    [6]

    Liang Y, Koslowski H R, Thomas P R, Nardon E, Alper B, Andrew P, Andrew Y, Arnoux G, Baranov Y, Becoulet M, Beurskens M, Biewer T, Bigi M, Crombe K, De La Luna E, de Vries P, Fundamenski W, Gerasimov S, Giroud C, Gryaznevich M P, Hawkes N, Hotchin S, Howell D, Jachmich S, Kiptily V, Moreira L, Parail V, Pinches S D, Rachlew E, Zimmermann O 2007 Phys. Rev. Lett. 98 265004Google Scholar

    [7]

    Suttrop W, Eich T, Fuchs J C, Gunter S, Janzer A, Herrmann A, Kallenbach A, Lang P T, Lunt T, Maraschek M, McDermott R M, Mlynek A, Putterich T, Rott M, Vierle T, Wolfrum E, Yu Q, Zammuto I, Zohm H, Team A U 2011 Phys. Rev. Lett. 106 225004Google Scholar

    [8]

    Evans T E, Moyer R A, Thomas P R, Watkins J G, Osborne T H, Boedo J A, Doyle E J, Fenstermacher M E, Finken K H, Groebner R J, Groth M, Harris J H, La Haye R J, Lasnier C J, Masuzaki S, Ohyabu N, Pretty D G, Rhodes T L, Reimerdes H, Rudakov D L, Schaffer M J, Wang G, Zeng L 2004 Phys. Rev. Lett. 92 235003Google Scholar

    [9]

    Jeon Y M, Park J K, Yoon S W, Ko W H, Lee S G, Lee K D, Yun G S, Nam Y U, Kim W C, Kwak J G, Lee K S, Kim H K, Yang H L, Team K 2012 Phys. Rev. Lett. 109 035004Google Scholar

    [10]

    Kirk A, Suttrop W, Chapman I T, Liu Y, Scannell R, Thornton A J, Orte L B, Cahyna P, Eich T, Fischer R, Fuchs C, Ham C, Harrison J R, Jakubowski M W, Kurzan B, Pamela S, Peterka M, Ryan D, Saarelma S, Sieglin B, Valovic M, Willensdorfer M 2015 Nucl. Fusion 55 043011Google Scholar

    [11]

    Liang Y, Koslowski H R, Thomas P R, Nardon E, Alper B, Andrew P, Andrew Y, Arnoux G, Baranov Y, Bécoulet M, Beurskens M, Biewer T, Bigi M, Crombe K, De La Luna E, de Vries P, Fundamenski W, Gerasimov S, Giroud C, Gryaznevich M P, Hawkes N, Hotchin S, Howell D, Jachmich S, Kiptily V, Moreira L, Parail V, Pinches S D, Rachlew E, Zimmermann O 2007 Physical Review Letters 98 265004

    [12]

    Sun Y, Liang Y, Liu Y Q, Gu S, Yang X, Guo W, Shi T, Jia M, Wang L, Lyu B, Zhou C, Liu A, Zang Q, Liu H, Chu N, Wang H H, Zhang T, Qian J, Xu L, He K, Chen D, Shen B, Gong X, Ji X, Wang S, Qi M, Song Y, Yuan Q, Sheng Z, Gao G, Fu P, Wan B 2016 Phys. Rev. Lett. 117 115001Google Scholar

    [13]

    Wan B N, Liang Y, Gong X Z, Xiang N, Xu G S, Sun Y, Wang L, Qian J P, Liu H Q, Zeng L, Zhang L, Zhang X J, Ding B J, Zang Q, Lyu B, Garofalo A M, Ekedahl A, Li M H, Ding F, Ding S Y, Du H F, Kong D F, Yu Y, Yang Y, Luo Z P, Huang J, Zhang T, Zhang Y, Li G Q, Xia T Y 2019 Nucl. Fusion 59 112003Google Scholar

    [14]

    Duan X R, Liu Y, Xu M, Yan L W, Xu Y, Song X M, Dong J Q, Ding X T, Chen L Y, Lu B, Liu D Q, Rao J, Xuan W M, Yang Q W, Zheng G Y, Zou X L, Liu Y Q, Zhong W L, Zhao K J, Ji X Q, Mao W C, Wang Q M, Li Q, Cao J Y, Cao Z, Lei G J, Zhang J H, Li X D, Bai X Y, Cheng J, Chen W, Cui Z Y, Delpech L, Diamond P H, Dong Y B, Ekedahl A, Hoang T, Huang Y, Ida K, Itoh K, Itoh S I, Isobe M, Inagaki S, Mazon D, Morita S, Peysson Y, Shi Z B, Wang X G, Xiao G L, Yu D L, Yu L M, Zhang Y P, Zhou Y, Cui C H, Feng B B, Huang M, Li Y G, Li B, Li G S, Li H J, Li Q, Peng J F, Wang Y Q, Yuan B S, Liu Y 2017 Nucl. Fusion 57 102013Google Scholar

    [15]

    Ding Y, Chen Z, Chen Z, Yang Z, Wang N, Hu Q, Rao B, Chen J, Cheng Z, Gao L, Jiang Z, Wang L, Wang Z, Zhang X, Zheng W, Zhang M, Zhuang G, Yu Q, Liang Y, Yu K, Hu X, Pan Y, Gentle K W, Team J T 2018 Plasma Sci. Technol. 20 125101Google Scholar

    [16]

    Haskey S R, Lanctot M J, Liu Y Q, Hanson J M, Blackwell B D, Nazikian R 2014 Plasma Phys. Contr. F. 56 035005Google Scholar

    [17]

    Schaffer M J, Menard J E, Aldan M P, Bialek J M, Evans T E, Moyer R A 2008 Nucl. Fusion 48 024004Google Scholar

    [18]

    Liu Y Q, Kirk A, Sun Y, Cahyna P, Chapman I T, Denner P, Fishpool G, Garofalo A M, Harrison J R, Nardon E 2012 Plasma Phys. Contr. F. 54 124013Google Scholar

    [19]

    Liu Y, Li L, Loarte A, Pinches S D, Polevoi A 2021 Nucl. Fusion 61 106029Google Scholar

    [20]

    苏春燕, 牟茂淋, 陈少永, 郭文平, 唐昌建 2021 物理学报 70 095207Google Scholar

    Su C Y, Mou M L, Chen S Y, Guo W P, Tang C J 2021 Acta Phys. Sin. 70 095207Google Scholar

    [21]

    Zhou L, Liu Y, Liu Y, Yang X 2016 Plasma Phys. Contr. F. 58 115003Google Scholar

    [22]

    陈撷宇, 牟茂淋, 苏春燕, 陈少永, 唐昌建 2020 物理学报 69 195201Google Scholar

    Chen X Y, Mou M L, Su C Y, Chen S Y, Tang C J 2020 Acta Phys. Sin. 69 195201Google Scholar

    [23]

    李春雨, 郝广周, 刘钺强, 王炼, 刘艺慧子 2022 物理学报 71 075202Google Scholar

    Li C Y, Hao G Z, Liu Y Q, Wang L, Liu Y H Z 2022 Acta Phys. Sin. 71 075202Google Scholar

    [24]

    Liu Y, Chu M S, Chapman I T, Hender T C 2008 Phys. Plasmas 15 112503Google Scholar

    [25]

    Liu Y, Kirk A, Nardon E 2010 Phys. Plasmas 17 122502Google Scholar

    [26]

    Sun Y, Liang Y, Liu Y Q, Gu S, Yang X, Guo W, Shi T, Jia M, Wang L, Lyu B, Zhou C, Liu A, Zang Q, Liu H, Chu N, Wang H H, Zhang T, Qian J, Xu L, He K, Chen D, Shen B, Gong X, Ji X, Wang S, Qi M, Song Y, Yuan Q, Sheng Z, Gao G, Fu P, Wan B 2016 Physical Review Letters 117 115001

    [27]

    Liu Y Q, Bondeson A, Fransson C M, Lennartson B, Breitholtz C 2000 Phys. Plasmas 7 3681Google Scholar

    [28]

    Liu Y, Kirk A, Gribov Y, Gryaznevich M P, Hender T C, Nardon E 2011 Nucl. Fusion 51 083002Google Scholar

    [29]

    Wang Z R, Lanctot M J, Liu Y Q, Park J K, Menard J E 2015 Phys. Rev. Lett. 114 145005Google Scholar

    [30]

    Li L, Liu Y Q, Kirk A, Wang N, Liang Y, Ryan D, Suttrop W, Dunne M, Fischer R, Fuchs J C, Kurzan B, Piovesan P, Willensdorfer M, Zhong F C 2016 Nucl. Fusion 56 126007Google Scholar

    [31]

    Yang X, Sun Y, Liu Y, Gu S, Liu Y, Wang H, Zhou L, Guo W 2016 Plasma Phys. Contr. F. 58 114006Google Scholar

    [32]

    Liu Y, Kirk A, Li L, In Y, Nazikian R, Sun Y, Suttrop W, Lyons B, Ryan D, Wang S, Yang X, Zhou L 2017 Phys. Plasmas 24 056111Google Scholar

    [33]

    Bondeson A, Iacono R 1989 Phys. Fluids B Plasma Phys. 1 1431Google Scholar

    [34]

    Liu Y, Chapman I T, Saarelma S, Gryaznevich M P, Hender T C, Howell D F 2009 Plasma Phys. Contr. F. 51 115005Google Scholar

    [35]

    Liu Y, Ryan D, Kirk A, Li L, Suttrop W, Dunne M, Fischer R, Fuchs J C, Kurzan B, Piovesan P, Willensdorfer M 2016 Nucl. Fusion 56 056015Google Scholar

    [36]

    Wang Z, Park J-K, Menard J E, Liu Y, Kaye S M, Gerhardt S 2018 Nucl. Fusion 58 016015Google Scholar

    [37]

    Hu Q M, Nazikian R, Grierson B A, Logan N C, Paz-Soldan C, Yu Q 2020 Nucl. Fusion 60 076001Google Scholar

    [38]

    Wang S X, Liu H Q, Jie Y X, Ding W X, Zeng L, Sun Y W, Lian H, Zhu X, Zou Z Y, Lyu B, Li Y Y, Zang Q, Du H F, Zhou C, Liu A D, Zhang T, Gao W, Gao X 2018 Nucl. Fusion 58 112013Google Scholar

    [39]

    Zhou L, Liu Y, Wenninger R, Liu Y, Wang S, Yang X 2018 Nucl. Fusion 58 076025Google Scholar

    [40]

    Li L, Liu Y Q, Wang N, Kirk A, Koslowski H R, Liang Y, Loarte A, Ryan D, Zhong F C 2017 Plasma Phys. Contr. F. 59 044005Google Scholar

    [41]

    Wenninger R, Kembleton R, Bachmann C, Biel W, Bolzonella T, Ciattaglia S, Cismondi F, Coleman M, Donné A J H, Eich T, Fable E, Federici G, Franke T, Lux H, Maviglia F, Meszaros B, Pütterich T, Saarelma S, Snickers A, Villone F, Vincenzi P, Wolff D, Zohm H 2017 Nucl. Fusion 57 016011Google Scholar

    [42]

    Lütjens H, Bondeson A, Sauter O 1996 Comput. Phys. Commun. 97 219Google Scholar

    [43]

    Liu Y, Akers R, Chapman I T, Gribov Y, Hao G Z, Huijsmans G T A, Kirk A, Loarte A, Pinches S D, Reinke M, Ryan D, Sun Y, Wang Z R 2015 Nucl. Fusion 55 063027Google Scholar

    [44]

    Fenstermacher M E, Evans T E, Osborne T H, Schaffer M J, Aldan M P, deGrassie J S, Gohil P, Joseph I, Moyer R A, Snyder P B, Groebner R J, Jakubowski M, Leonard A W, Schmitz O, Team D 2008 Phys. Plasmas 15 056122Google Scholar

    [45]

    Gu S, Wan B, Sun Y, Chu N, Liu Y Q, Shi T, Wang H H, Jia M, He K 2019 Nucl. Fusion 59 126042Google Scholar

    [46]

    Nazikian R, Petty C C, Bortolon A, Chen X, Eldon D, Evans T E, Grierson B A, Ferraro N M, Haskey S R, Knolker M, Lasnier C, Logan N C, Moyer R A, Orlov D, Osborne T H, Paz-Soldan C, Turco F, Wang H Q, Weisberg D B 2018 Nucl. Fusion 58 106010Google Scholar

    [47]

    Hu Q M, Nazikian R, Logan N C, Park J K, Paz-Soldan C, Yang S M, Grierson B A, In Y, Jeon Y M, Kim M, Kim S K, Orlov D M, Park G Y, Yu Q 2021 Phys. Plasmas 28 052505Google Scholar

    [48]

    Federici G, Bachmann C, Barucca L, Baylard C, Biel W, Boccaccini L V, Bustreo C, Ciattaglia S, Cismondi F, Corato V, Day C, Diegele E, Franke T, Gaio E, Gliss C, Haertl T, Ibarra A, Holden J, Keech G, Kembleton R, Loving A, Maviglia F, Morris J, Meszaros B, Moscato I, Pintsuk G, Siccinio M, Taylor N, Tran M Q, Vorpahl C, Walden H, You J H 2019 Nucl. Fusion 59 066013Google Scholar

    [49]

    Zhou L, Liu Y, Hu H, Siccinio M, Maviglia F, Zohm H, Pigatto L, Wang Y, Li L, Hao G Z, Yang X, Zhang H, Duan P, Chen L 2023 Plasma Phys. Contr. F. 65 035008Google Scholar

    [50]

    Hu B, Betti R, Manickam J 2006 Phys. Plasmas 13 112505Google Scholar

    [51]

    Zhou L, Liu Y, Siccinio M, Fable E, Wu T, Kurki-Suonio T, Varje J, Liu D 2021 Plasma Phys. Contr. F. 63 065007Google Scholar

  • 图 1  等离子体平衡的径向剖面 (a)在固定的磁场下扫描等离子体电流时安全因子剖面的变化; (b)由${{B_0^2} \mathord{\left/ {\vphantom {{B_0^2} {{\mu _0}}}} \right. } {{\mu _0}}}$归一化的压强剖面; (c)磁轴处归一化为1的密度剖面; (d)由磁轴处阿尔芬频率${\omega _A} = {{{B_0}} \mathord{\left/ {\vphantom {{{B_0}} {\left[ {{R_0}\left( {{\mu _0}{\rho _0}} \right)} \right]}}} \right. } {\left[ {{R_0}\left( {{\mu _0}{\rho _0}} \right)} \right]}}$归一化的旋转频率剖面

    Fig. 1.  Plasma equilibrium radial profiles: (a) Variation of the equilibrium safety factor profile while scanning the plasma current at fixed field; (b) the plasma pressure normalized by ${{B_0^2} \mathord{\left/ {\vphantom {{B_0^2} {{\mu _0}}}} \right. } {{\mu _0}}}$; (c) the plasma density normalized to unity at the magnetic axis; (d) the (assumed) plasma toroidal rotation frequencies normalized by the on-axis Alfven frequency${\omega _A} = {{{B_0}} \mathord{\left/ {\vphantom {{{B_0}} {\left[ {{R_0}\left( {{\mu _0}{\rho _0}} \right)} \right]}}} \right. } {\left[ {{R_0}\left( {{\mu _0}{\rho _0}} \right)} \right]}}$.

    图 2  等离子体的边界(蓝线)、真空双壁(红线)和RMP线圈的几何位形(黑线)

    Fig. 2.  Plasma boundary (bule line), double wall shapes (red lines) and RMP coil geometry (black lines).

    图 3  在环向模数 (a)$n = 1$, (b)$n = 2$, (c)$n = 3$和(d)$n = 4$线圈位形下, 中线圈在最外层有理面处产生的径向扰动场幅值$ \left| {b_{{\text{res}}}^{\text{1}}} \right| $随安全因子${q_{95}}$的变化. 中线圈的极向宽度和电流分别为$ \Delta {\theta ^{\text{M}}} = 4{{\text{5}}^{\circ}} $$ {I^{\text{M}}} = 90{\text{ kAt}} $

    Fig. 3.  Comparison of the computed amplitude of the outermost pitch resonant radial field components$ \left| {b_{{\text{res}}}^{\text{1}}} \right| $, between the vacuum field (solid) and the total field including the plasma response (dashed), versus the edge safety factor q95, for the (a) n = 1, (b) n = 2, (c) n = 3 and (d) n = 4 coil configurations, respectively, using the middle row of RMP coils with the poloidal width $ \Delta {\theta ^{\text{M}}} = 4{{\text{5}}^{\circ}} $ and current $ {I^{\text{M}}} = 90{\text{ kAt}} $.

    图 4  在环向模数 (a)$n = 1$, (b)$n = 2$, (c)$n = 3$和(d)$n = 4$线圈位形下, 中线圈在X点附近产生的扰动位移幅值$\left| {{\xi _X}} \right|$随安全因子${q_{95}}$的变化, 中线圈的极向宽度和电流分别为$ \Delta {\theta ^{\text{M}}} = 4{{\text{5}}^{\circ}} $$ {I^{\text{M}}} = 90{\text{ kAt}} $

    Fig. 4.  The computed amplitude of the plasma surface displacement near the X-point $\left| {{\xi _X}} \right|$ versus the edge safety factor ${q_{95}}$, using the middle row of RMP coils with the poloidal width $ \Delta {\theta ^{\text{M}}} = 4{{\text{5}}^{\circ}} $and current $ {I^{\text{M}}} = 90{\text{ kAt}} $, for the (a)$n = 1$, (b)$n = 2$, (c)$n = 3$ and(d)$n = 4$ coil configurations, respectively.

    图 5  在环向模数$n = 1$线圈位形下, $ {q_{95}} = 4 $, 4.25, 4.4和4.55时有理面处相应总径向扰动场$b_{{\text{res(tot)}}}^1$的对比. 红线(${q_{95}} = 4$)和蓝线(${q_{95}} = 4.4$)分别对应最外层有理面处总径向扰动场或X点附近扰动位移的谷值和峰值, 如图3(a)图4(a)中红点和蓝点所示

    Fig. 5.  Comparison of the resonant field amplitude at the corresponding rational surfaces among $ {q_{95}} =4, {\text{ }}4.25, {\text{ }}4.4, $$ {\text{ }}4.55 $ with $n = 1$. The red line (${q_{95}} = 4$) and blue line (${q_{95}} = 4.4$) indicate the valley and peak values of the amplitude of the outermost pitch resonant radial field components in Fig. 3(a) or the plasma surface displacement near the X-point in Fig. 4(a), respectively.

    图 6  最外侧有理面处归一化的(a)(c)(e)(g)真空径向场和(b)(d)(f)(h)总径向场(包括等离子体响应)随上下两组线圈电流相位差$ \Delta {\varPhi ^{{\text{UL}}}} = {\varPhi ^{\text{U}}} - {\varPhi ^{\text{L}}} $和安全因子${q_{95}}$的变化. 环向模数分别为(a)(b)n = 1, (c)(d)n = 2, (e)(f)n = 3和(g)(h)n = 4. 上下两组线圈的极向位置分别为$\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$$\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$, 极向宽度和电流分别为$\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$$ {I^{\text{U}}} = {I^{\text{L}}} = 90{\text{ kAt}} $

    Fig. 6.  Comparison of the amplitude of the outermost pitch resonant radial field component in 2 D parameter space ($\Delta \varPhi , {q_{95}}$), between the vacuum radial field (left panel) and the total radial field including the plasma response (right panel), for the toroidal number (a)(b) n = 1, (c)(d) n = 2, (e)(f) n = 3, and (g)(h) n = 4, respectively, using upper and lower rows of coils located at $\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$and $\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$ with poloidal width $\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$ and current $ {I^{\text{U}}} = {I^{\text{L}}} = 90{\text{ kAt}} $. The field amplitude is linearly scaled to the range of [0, 1] for each q95 value.

    图 7  X点附近扰动位移随上下两组线圈电流相位差$ \Delta {\varPhi ^{{\text{UL}}}} = {\varPhi ^{\text{U}}} - {\varPhi ^{\text{L}}} $和安全因子${q_{95}}$的变化. 环向模数分别为(a) n = 1, (b) n = 2, (c) n = 3和(d) n = 4.上下两组线圈的极向位置分别为$\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$$\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$, 极向宽度和电流分别为$\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$$ {I^{\text{U}}} = {I^{\text{L}}} = 90{\text{ kAt}} $

    Fig. 7.  Amplitude of the plasma surface displacement near the X-point, with 2D parameter scan in toroidal phase difference $ \Delta {\varPhi ^{{\text{UL}}}} = {\varPhi ^{\text{U}}} - {\varPhi ^{\text{L}}} $(vertical axis) between the two offmidplane rows and q95 (horizontal axis), for the toroidal number (a) n = 1, (b) n = 2, (c) n = 3, and (d) n = 4, respectively, using upper and lower rows of coils located at $\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$and $\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$ with poloidal width $\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$ and current $ {I^{\text{U}}} = {I^{\text{L}}} = 90{\text{ kAt}} $.

    图 8  在环向模数 (a)$n = 1$, (b)$n = 2$, (c)$n = 3$和(d)$n = 4$线圈位形下, 比较线圈电流幅值相等和优化两种情况下X点附近扰动位移随上下两组线圈电流相位差$ \Delta {\varPhi ^{{\text{UL}}}} = {\varPhi ^{\text{U}}} - {\varPhi ^{\text{L}}} $的变化. 上下两组线圈的极向位置分别为$\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$$\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$, 极向宽度为$\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$, 两组线圈的总电流固定为180 kAt

    Fig. 8.  Comparison of the amplitude of the plasma surface displacement near the X-point between the equal coil current and optimized coil current, versus the toroidal phase difference $ \Delta {\varPhi ^{{\text{UL}}}} = {\varPhi ^{\text{U}}} - {\varPhi ^{\text{L}}} $between the upper and lower rows of coils located at $\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$and $\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$ with poloidal width $\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$, for the toroidal number (a) n = 1, (b) n = 2, (c) n = 3, and (d) n = 4, respectively. The total current of the two rows of coils is fixed at 180 kAt.

    图 9  在环向模数$n = 1$线圈位形下, 比较线圈电流幅值(a)相等和(b)优化两种条件下, X点附近扰动位移随上、下两组线圈与中线圈电流相位差($ {\varPhi ^{\text{U}}} - {\varPhi ^{\text{M}}} $, $ {\varPhi ^{\text{L}}} - {\varPhi ^{\text{M}}} $)的变化. 上中下三组线圈的极向位置分别为$\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$, $\theta _{\text{c}}^{\text{M}} = {0^{\circ}}$$\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$, 极向宽度为$\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$$\Delta {\theta ^{\text{M}}} = 4{{\text{5}}^{\circ}}$, 三组线圈的总电流固定为270 kAt

    Fig. 9.  Comparison of the amplitude of the plasma surface displacement near the X-point between the (a) equal coil current and (b) optimized coil current for the toroidal number n=1. The relative toroidal phasing, ($ {\varPhi ^{\text{U}}} - {\varPhi ^{\text{M}}} $, $ {\varPhi ^{\text{L}}} - {\varPhi ^{\text{M}}} $), of the upper and lower rows of coil currents with respect to the middle row, is scanned in the 2 D parameter space. The coils located at $\theta _{\text{c}}^{\text{U}} = + {20^{\circ}}$, $\theta _{\text{c}}^{\text{M}} = {0^{\circ}}$ and $\theta _{\text{c}}^{\text{L}} = - {20^{\circ}}$ with poloidal width $\Delta {\theta ^{\text{U}}} = \Delta {\theta ^{\text{L}}} = {\text{1}}{{\text{5}}^{\circ}}$ and $\Delta {\theta ^{\text{M}}} = 4{{\text{5}}^{\circ}}$. The total current of the three rows of coils is fixed at 270 kAt

    图 10  在强平行声波阻尼(${\kappa _\parallel } = 1.5$)情况下, 比较流体响应、包含背景粒子的动理学响应(TP)以及包含背景粒子和聚变产生α粒子的动理学响应(TP+EP)对应的n = 1总径向扰动场沿小半径的最大幅值. 对于(a)${q_{95}} = 3.27$和(b)${q_{95}} = 6.54$, 共振谐波分别为m = 1—5和m = 2—10, 其他m为非共振谐波

    Fig. 10.  The maximal amplitude (along the minor radius) of all the poloidal Fourier harmonics of the n=1 total radial field. The resonant harmonics are m = 1—5 for (a) ${q_{95}} = 3.27$ and m = 2—10 for (b) ${q_{95}} = 6.54$, and the remaining harmonics are nonresonant. Compared are the response fields obtained assuming the fluid model (fluid), and the MHD-kinetic hybrid model including the non-adiabatic contributions from thermal particles (TP), or both thermal particles and energetic particles (i.e. fusion-born alphas) (EP+TP). A strong parallel sound wave damping model is assumed for both plasmas (${\kappa _\parallel } = 1.5$).

    图 11  在无平行声波阻尼(${\kappa _\parallel } = 0$)情况下, 比较流体响应(Fluid)、包含背景粒子的动理学响应(TP)以及包含背景粒子和聚变产生α粒子的动理学响应(TP+EP)对应的n=1总径向扰动场沿小半径的最大振幅. 对于(a)${q_{95}} = 3.27$和(b)${q_{95}} = 6.54$, 共振谐波分别为m = 1—5和m = 2—10, 其他m为非共振谐波

    Fig. 11.  The maximal amplitude (along the minor radius) of all the poloidal Fourier harmonics of the n=1 total radial field. The resonant harmonics are m = 1—5 for (a) ${q_{95}} = 3.27$ and m = 2—10 for (b) ${q_{95}} = 6.54$, and the remaining harmonics are nonresonant. Compared are the response fields obtained assuming the fluid model, and the MHD-kinetic hybrid model including the non-adiabatic contributions from thermal particles (TP), or both thermal particles and energetic particles (i.e. fusion-born alphas) (EP+TP). The parallel sound wave damping model is eliminated for both plasmas (${\kappa _\parallel } = 0$).

    图 12  在无平行声波阻尼(${\kappa _\parallel } = 0$)情况下, 比较DEMO平衡(${q_{95}} = 3.27$)的(a)流体响应、(b)包含背景粒子的动理学响应以及(c)包含背景粒子和聚变产生α粒子的动理学响应对应的n = 1等离子体径向位移沿法向分量的振幅

    Fig. 12.  Comparison of the amplitude of the normal component of the computed plasma radial displacement, due to the plasma response to the applied n = 1 RMP field for ${q_{95}} = 3.27$, assuming (a) the fluid model, and the MHD-kinetic hybrid model including non-adiabatic contributions from (b) thermal particles, and (c) both fusion-born alphas and thermal particles. The parallel sound wave damping model is eliminated (${\kappa _\parallel } = 0$).

    表 1  在流体响应和动理学响应计算过程中扫描参数的相关信息

    Table 1.  Parameter information used to compute fluid response and kinetic response.

    流体响应动理学响应(TP, TP+EP)
    $n = 1—4$$n = 1$
    ${\kappa _\parallel } = 1.5$${\kappa _\parallel } = 1.5$${\kappa _\parallel } = 0$
    中线圈上下两组线圈上中下三组线圈中线圈
    ${q_{95} } = 3.0—6.5$${q_{95}} = 3.27$$\begin{gathered}{q_{95}} = 3.27\left( {{\beta _{\text{N}}} = 2.69} \right)\\{q_{95}} = 6.54\left( {{\beta _{\text{N}}} = 1.35} \right)\end{gathered}$
    $\begin{gathered} \Delta {\varPhi ^{ {\text{UL} } } } = {\varPhi ^{\text{U} } } - {\varPhi ^{\text{L} } } \\ = - {180^{\circ} }—{180^{\circ} } \end{gathered}$$\begin{gathered}{\varPhi ^{\text{U} } } - {\varPhi ^{\text{M} } } = - {180^{\circ} }—{180^{\circ} }\\{\varPhi ^{\text{L} } } - {\varPhi ^{\text{M} } } = - {180^{\circ} }—{180^{\circ} }\end{gathered}$
    $ {I^{\text{M}}} = 90{\text{ kAt}} $$ \begin{gathered}{I^{\text{U}}} = {I^{\text{L}}} = 90{\text{ kAt}}\\ {I^{\text{U}}} + {I^{\text{L}}} = 180{\text{ kAt}} \end{gathered}$$\begin{gathered} {I^{\text{U}}} = {I^{\text{M}}} = {I^{\text{L}}} = 90{\text{ kAt}}\\{I^{\text{U}}} + {I^{\text{M}}} + {I^{\text{L}}} = 270{\text{ kAt}} \end{gathered}$$ {I^{\text{M}}} = 90{\text{ kAt}} $
    下载: 导出CSV

    表 2  不同环向模数下, 电流为90 kAt时单组上/下线圈在X点附近产生扰动位移的幅值和相位

    Table 2.  Amplitude and phase of the plasma surface displacement near the X-point for different toroidal number, using only upper/lower row of coils with 90 kAt current.

    单组上线圈单组下线圈
    $n$$\left| {{\xi _X}} \right|$/mm$\varPhi /\left( ^\circ \right)$$\left| {{\xi _X}} \right|$/mm$\varPhi /\left( ^\circ \right)$
    139.98$ - 155.8$39.41$ - 67.3$
    216.19$ - 156.4$11.16$ - 48.1$
    33.46$ - 107.0$11.09$22.4$
    46.90$149.4$1.20$ - 98.8$
    下载: 导出CSV

    表 3  上下两组线圈电流幅值和相位差的优化结果

    Table 3.  Optimization results of the current amplitude and phase difference between the upper and lower rows of coils.

    $n$${I^{\text{U}}}/{\text{kAt}}$${I^{\text{L}}}/{\text{kAt}}$$ ({\varPhi ^{\text{U}}} - {\varPhi ^{\text{L}}})/(^\circ ) $
    190.6489.36$88.5$
    2106.5673.44$108.3$
    342.80137.20$ 129.4 $
    4153.3426.66$ 111.8 $
    下载: 导出CSV

    表 4  不同环向模数下, 电流为90 kAt时单组中线圈在X点附近产生扰动位移的幅值和相位

    Table 4.  Amplitude and phase of the plasma surface displacement near the X-point for different toroidal number, using only middle row of coils with 90 kAt current.

    $n$$\left| {{\xi _X}} \right|$/mm$\varPhi {\text{/(}}^\circ )$
    1$70.57$$ - 110.8$
    25.52$ - 102.5$
    312.30$ - 39.0$
    46.33$ - 178.8$
    下载: 导出CSV

    表 5  上中下三组线圈电流幅值和相位差的优化结果

    Table 5.  Optimization results of the current amplitude and phasing with three rows of coils.

    $n$${I^{\text{L}}}/{\text{kAt}}$${I^{\text{M}}}/{\text{kAt}}$${I^{\text{U}}}/{\text{kAt}}$$({\varPhi ^{\text{L} } } - {\varPhi ^{\text{M} } }) $$ /(^\circ )$$({\varPhi ^{\text{U} } } - {\varPhi ^{\text{M} } }) $$ /(^\circ )$
    170.95127.0572.00$ - 43.5$$45.0$
    291.6845.33132.99$ - 54.4 $$53.9$
    3111.52123.6934.79$ - 61.4$$68.0$
    422.44118.44129.12$ - 80.0$$31.8$
    下载: 导出CSV
  • [1]

    Suttrop W 2000 Plasma Phys. Contr. F. 42 A1Google Scholar

    [2]

    Loarte A, Lipschultz B, Kukushkin A S, Matthews G F, Stangeby P C, Asakura N, Counsell G F, Federici G, Kallenbach A, Krieger K, Mahdavi A, Philipps V, Reiter D, Roth J, Strachan J, Whyte D, Doerner R, Eich T, Fundamenski W, Herrmann A, Fenstermacher M, Ghendrih P, Groth M, Kirschner A, Konoshima S, LaBombard B, Lang P, Leonard A W, Monier-Garbet P, Neu R, Pacher H, Pegourie B, Pitts R A, Takamura S, Terry J, Tsitrone E, Group D P T 2007 Nucl. Fusion 47 S203Google Scholar

    [3]

    Ryter F, Fuchs J, Schneider W, Sips A, Stäbler A, Stober J, Team A U 2008 J. Phys. Conf. Ser. 123 012035Google Scholar

    [4]

    Loarte A, Saibene G, Sartori R, Becoulet M, Horton L, Eich T, Herrmann A, Laux M, Matthews G, Jachmich S, Asakura N, Chankin A, Leonard A, Porter G, Federici G, Shimada M, Sugihara M, Janeschitz G 2003 J. Nucl. Mater 313 962Google Scholar

    [5]

    Wenninger R P, Bernert M, Eich T, Fable E, Federici G, Kallenbach A, Loarte A, Lowry C, McDonald D, Neu R, Pütterich T, Schneider P, Sieglin B, Strohmayer G, Reimold F, Wischmeier M 2014 Nucl. Fusion 54 114003Google Scholar

    [6]

    Liang Y, Koslowski H R, Thomas P R, Nardon E, Alper B, Andrew P, Andrew Y, Arnoux G, Baranov Y, Becoulet M, Beurskens M, Biewer T, Bigi M, Crombe K, De La Luna E, de Vries P, Fundamenski W, Gerasimov S, Giroud C, Gryaznevich M P, Hawkes N, Hotchin S, Howell D, Jachmich S, Kiptily V, Moreira L, Parail V, Pinches S D, Rachlew E, Zimmermann O 2007 Phys. Rev. Lett. 98 265004Google Scholar

    [7]

    Suttrop W, Eich T, Fuchs J C, Gunter S, Janzer A, Herrmann A, Kallenbach A, Lang P T, Lunt T, Maraschek M, McDermott R M, Mlynek A, Putterich T, Rott M, Vierle T, Wolfrum E, Yu Q, Zammuto I, Zohm H, Team A U 2011 Phys. Rev. Lett. 106 225004Google Scholar

    [8]

    Evans T E, Moyer R A, Thomas P R, Watkins J G, Osborne T H, Boedo J A, Doyle E J, Fenstermacher M E, Finken K H, Groebner R J, Groth M, Harris J H, La Haye R J, Lasnier C J, Masuzaki S, Ohyabu N, Pretty D G, Rhodes T L, Reimerdes H, Rudakov D L, Schaffer M J, Wang G, Zeng L 2004 Phys. Rev. Lett. 92 235003Google Scholar

    [9]

    Jeon Y M, Park J K, Yoon S W, Ko W H, Lee S G, Lee K D, Yun G S, Nam Y U, Kim W C, Kwak J G, Lee K S, Kim H K, Yang H L, Team K 2012 Phys. Rev. Lett. 109 035004Google Scholar

    [10]

    Kirk A, Suttrop W, Chapman I T, Liu Y, Scannell R, Thornton A J, Orte L B, Cahyna P, Eich T, Fischer R, Fuchs C, Ham C, Harrison J R, Jakubowski M W, Kurzan B, Pamela S, Peterka M, Ryan D, Saarelma S, Sieglin B, Valovic M, Willensdorfer M 2015 Nucl. Fusion 55 043011Google Scholar

    [11]

    Liang Y, Koslowski H R, Thomas P R, Nardon E, Alper B, Andrew P, Andrew Y, Arnoux G, Baranov Y, Bécoulet M, Beurskens M, Biewer T, Bigi M, Crombe K, De La Luna E, de Vries P, Fundamenski W, Gerasimov S, Giroud C, Gryaznevich M P, Hawkes N, Hotchin S, Howell D, Jachmich S, Kiptily V, Moreira L, Parail V, Pinches S D, Rachlew E, Zimmermann O 2007 Physical Review Letters 98 265004

    [12]

    Sun Y, Liang Y, Liu Y Q, Gu S, Yang X, Guo W, Shi T, Jia M, Wang L, Lyu B, Zhou C, Liu A, Zang Q, Liu H, Chu N, Wang H H, Zhang T, Qian J, Xu L, He K, Chen D, Shen B, Gong X, Ji X, Wang S, Qi M, Song Y, Yuan Q, Sheng Z, Gao G, Fu P, Wan B 2016 Phys. Rev. Lett. 117 115001Google Scholar

    [13]

    Wan B N, Liang Y, Gong X Z, Xiang N, Xu G S, Sun Y, Wang L, Qian J P, Liu H Q, Zeng L, Zhang L, Zhang X J, Ding B J, Zang Q, Lyu B, Garofalo A M, Ekedahl A, Li M H, Ding F, Ding S Y, Du H F, Kong D F, Yu Y, Yang Y, Luo Z P, Huang J, Zhang T, Zhang Y, Li G Q, Xia T Y 2019 Nucl. Fusion 59 112003Google Scholar

    [14]

    Duan X R, Liu Y, Xu M, Yan L W, Xu Y, Song X M, Dong J Q, Ding X T, Chen L Y, Lu B, Liu D Q, Rao J, Xuan W M, Yang Q W, Zheng G Y, Zou X L, Liu Y Q, Zhong W L, Zhao K J, Ji X Q, Mao W C, Wang Q M, Li Q, Cao J Y, Cao Z, Lei G J, Zhang J H, Li X D, Bai X Y, Cheng J, Chen W, Cui Z Y, Delpech L, Diamond P H, Dong Y B, Ekedahl A, Hoang T, Huang Y, Ida K, Itoh K, Itoh S I, Isobe M, Inagaki S, Mazon D, Morita S, Peysson Y, Shi Z B, Wang X G, Xiao G L, Yu D L, Yu L M, Zhang Y P, Zhou Y, Cui C H, Feng B B, Huang M, Li Y G, Li B, Li G S, Li H J, Li Q, Peng J F, Wang Y Q, Yuan B S, Liu Y 2017 Nucl. Fusion 57 102013Google Scholar

    [15]

    Ding Y, Chen Z, Chen Z, Yang Z, Wang N, Hu Q, Rao B, Chen J, Cheng Z, Gao L, Jiang Z, Wang L, Wang Z, Zhang X, Zheng W, Zhang M, Zhuang G, Yu Q, Liang Y, Yu K, Hu X, Pan Y, Gentle K W, Team J T 2018 Plasma Sci. Technol. 20 125101Google Scholar

    [16]

    Haskey S R, Lanctot M J, Liu Y Q, Hanson J M, Blackwell B D, Nazikian R 2014 Plasma Phys. Contr. F. 56 035005Google Scholar

    [17]

    Schaffer M J, Menard J E, Aldan M P, Bialek J M, Evans T E, Moyer R A 2008 Nucl. Fusion 48 024004Google Scholar

    [18]

    Liu Y Q, Kirk A, Sun Y, Cahyna P, Chapman I T, Denner P, Fishpool G, Garofalo A M, Harrison J R, Nardon E 2012 Plasma Phys. Contr. F. 54 124013Google Scholar

    [19]

    Liu Y, Li L, Loarte A, Pinches S D, Polevoi A 2021 Nucl. Fusion 61 106029Google Scholar

    [20]

    苏春燕, 牟茂淋, 陈少永, 郭文平, 唐昌建 2021 物理学报 70 095207Google Scholar

    Su C Y, Mou M L, Chen S Y, Guo W P, Tang C J 2021 Acta Phys. Sin. 70 095207Google Scholar

    [21]

    Zhou L, Liu Y, Liu Y, Yang X 2016 Plasma Phys. Contr. F. 58 115003Google Scholar

    [22]

    陈撷宇, 牟茂淋, 苏春燕, 陈少永, 唐昌建 2020 物理学报 69 195201Google Scholar

    Chen X Y, Mou M L, Su C Y, Chen S Y, Tang C J 2020 Acta Phys. Sin. 69 195201Google Scholar

    [23]

    李春雨, 郝广周, 刘钺强, 王炼, 刘艺慧子 2022 物理学报 71 075202Google Scholar

    Li C Y, Hao G Z, Liu Y Q, Wang L, Liu Y H Z 2022 Acta Phys. Sin. 71 075202Google Scholar

    [24]

    Liu Y, Chu M S, Chapman I T, Hender T C 2008 Phys. Plasmas 15 112503Google Scholar

    [25]

    Liu Y, Kirk A, Nardon E 2010 Phys. Plasmas 17 122502Google Scholar

    [26]

    Sun Y, Liang Y, Liu Y Q, Gu S, Yang X, Guo W, Shi T, Jia M, Wang L, Lyu B, Zhou C, Liu A, Zang Q, Liu H, Chu N, Wang H H, Zhang T, Qian J, Xu L, He K, Chen D, Shen B, Gong X, Ji X, Wang S, Qi M, Song Y, Yuan Q, Sheng Z, Gao G, Fu P, Wan B 2016 Physical Review Letters 117 115001

    [27]

    Liu Y Q, Bondeson A, Fransson C M, Lennartson B, Breitholtz C 2000 Phys. Plasmas 7 3681Google Scholar

    [28]

    Liu Y, Kirk A, Gribov Y, Gryaznevich M P, Hender T C, Nardon E 2011 Nucl. Fusion 51 083002Google Scholar

    [29]

    Wang Z R, Lanctot M J, Liu Y Q, Park J K, Menard J E 2015 Phys. Rev. Lett. 114 145005Google Scholar

    [30]

    Li L, Liu Y Q, Kirk A, Wang N, Liang Y, Ryan D, Suttrop W, Dunne M, Fischer R, Fuchs J C, Kurzan B, Piovesan P, Willensdorfer M, Zhong F C 2016 Nucl. Fusion 56 126007Google Scholar

    [31]

    Yang X, Sun Y, Liu Y, Gu S, Liu Y, Wang H, Zhou L, Guo W 2016 Plasma Phys. Contr. F. 58 114006Google Scholar

    [32]

    Liu Y, Kirk A, Li L, In Y, Nazikian R, Sun Y, Suttrop W, Lyons B, Ryan D, Wang S, Yang X, Zhou L 2017 Phys. Plasmas 24 056111Google Scholar

    [33]

    Bondeson A, Iacono R 1989 Phys. Fluids B Plasma Phys. 1 1431Google Scholar

    [34]

    Liu Y, Chapman I T, Saarelma S, Gryaznevich M P, Hender T C, Howell D F 2009 Plasma Phys. Contr. F. 51 115005Google Scholar

    [35]

    Liu Y, Ryan D, Kirk A, Li L, Suttrop W, Dunne M, Fischer R, Fuchs J C, Kurzan B, Piovesan P, Willensdorfer M 2016 Nucl. Fusion 56 056015Google Scholar

    [36]

    Wang Z, Park J-K, Menard J E, Liu Y, Kaye S M, Gerhardt S 2018 Nucl. Fusion 58 016015Google Scholar

    [37]

    Hu Q M, Nazikian R, Grierson B A, Logan N C, Paz-Soldan C, Yu Q 2020 Nucl. Fusion 60 076001Google Scholar

    [38]

    Wang S X, Liu H Q, Jie Y X, Ding W X, Zeng L, Sun Y W, Lian H, Zhu X, Zou Z Y, Lyu B, Li Y Y, Zang Q, Du H F, Zhou C, Liu A D, Zhang T, Gao W, Gao X 2018 Nucl. Fusion 58 112013Google Scholar

    [39]

    Zhou L, Liu Y, Wenninger R, Liu Y, Wang S, Yang X 2018 Nucl. Fusion 58 076025Google Scholar

    [40]

    Li L, Liu Y Q, Wang N, Kirk A, Koslowski H R, Liang Y, Loarte A, Ryan D, Zhong F C 2017 Plasma Phys. Contr. F. 59 044005Google Scholar

    [41]

    Wenninger R, Kembleton R, Bachmann C, Biel W, Bolzonella T, Ciattaglia S, Cismondi F, Coleman M, Donné A J H, Eich T, Fable E, Federici G, Franke T, Lux H, Maviglia F, Meszaros B, Pütterich T, Saarelma S, Snickers A, Villone F, Vincenzi P, Wolff D, Zohm H 2017 Nucl. Fusion 57 016011Google Scholar

    [42]

    Lütjens H, Bondeson A, Sauter O 1996 Comput. Phys. Commun. 97 219Google Scholar

    [43]

    Liu Y, Akers R, Chapman I T, Gribov Y, Hao G Z, Huijsmans G T A, Kirk A, Loarte A, Pinches S D, Reinke M, Ryan D, Sun Y, Wang Z R 2015 Nucl. Fusion 55 063027Google Scholar

    [44]

    Fenstermacher M E, Evans T E, Osborne T H, Schaffer M J, Aldan M P, deGrassie J S, Gohil P, Joseph I, Moyer R A, Snyder P B, Groebner R J, Jakubowski M, Leonard A W, Schmitz O, Team D 2008 Phys. Plasmas 15 056122Google Scholar

    [45]

    Gu S, Wan B, Sun Y, Chu N, Liu Y Q, Shi T, Wang H H, Jia M, He K 2019 Nucl. Fusion 59 126042Google Scholar

    [46]

    Nazikian R, Petty C C, Bortolon A, Chen X, Eldon D, Evans T E, Grierson B A, Ferraro N M, Haskey S R, Knolker M, Lasnier C, Logan N C, Moyer R A, Orlov D, Osborne T H, Paz-Soldan C, Turco F, Wang H Q, Weisberg D B 2018 Nucl. Fusion 58 106010Google Scholar

    [47]

    Hu Q M, Nazikian R, Logan N C, Park J K, Paz-Soldan C, Yang S M, Grierson B A, In Y, Jeon Y M, Kim M, Kim S K, Orlov D M, Park G Y, Yu Q 2021 Phys. Plasmas 28 052505Google Scholar

    [48]

    Federici G, Bachmann C, Barucca L, Baylard C, Biel W, Boccaccini L V, Bustreo C, Ciattaglia S, Cismondi F, Corato V, Day C, Diegele E, Franke T, Gaio E, Gliss C, Haertl T, Ibarra A, Holden J, Keech G, Kembleton R, Loving A, Maviglia F, Morris J, Meszaros B, Moscato I, Pintsuk G, Siccinio M, Taylor N, Tran M Q, Vorpahl C, Walden H, You J H 2019 Nucl. Fusion 59 066013Google Scholar

    [49]

    Zhou L, Liu Y, Hu H, Siccinio M, Maviglia F, Zohm H, Pigatto L, Wang Y, Li L, Hao G Z, Yang X, Zhang H, Duan P, Chen L 2023 Plasma Phys. Contr. F. 65 035008Google Scholar

    [50]

    Hu B, Betti R, Manickam J 2006 Phys. Plasmas 13 112505Google Scholar

    [51]

    Zhou L, Liu Y, Siccinio M, Fable E, Wu T, Kurki-Suonio T, Varje J, Liu D 2021 Plasma Phys. Contr. F. 63 065007Google Scholar

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出版历程
  • 收稿日期:  2022-11-18
  • 修回日期:  2023-01-24
  • 上网日期:  2023-02-11
  • 刊出日期:  2023-04-05

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