Theoretical Studies of Low-frequency Shear Alfvén Waves in Reversed Shear Tokamak Plasmas

IF 0.8 4区物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY

物理学报 Pub Date : 2023-01-01 DOI:10.7498/aps.72.20230255

Ma Rui-Rui, Chen Liu, Qiu Zhi-Yong

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引用次数: 0

Abstract

The low-frequency Alfvénic fluctuations in the kinetic thermal-ion gap frequency range have been of research interest since they can interact with both thermal and energetic particles. In this work, linear wave properties of the low-frequency shear Alfvén waves excited by energetic and/or thermal particles observed in tokamak experiments with reversed magnetic shear are theoretically investigated and delineated in the theoretical framework of the generalized fishbone-like dispersion relation (GFLDR). Since these low-frequency shear Alfvén waves are closely related to the dedicated experiment of energetic ion-driven low-frequency instabilities conducted on DIII-D in 2019, this work demonstrates, by adopting the representative experimental equilibrium parameters of DIII-D, that the experimentally observed lowfrequency modes and beta-induced Alfvén eigenmodes (BAEs) are, respectively, the reactive-type and dissipative-type unstable modes with dominant Alfvénic polarization, thus the former being more precisely called low-frequency Alfvén modes (LFAMs). More specifically, due to diamagnetic and trapped particle effects, the LFAM can be coupled with the beta-induced Alfvén-acoustic mode (BAAE) in the low-frequency region (frequency much less than the thermal-ion transit and/or bounce frequency); or with the BAE in the high frequency region (frequency higher than or comparable to the thermal-ion transit frequency); resulting in reactive-type instabilities. Moreover, due to different instability mechanisms, the maximal drive of BAEs occurs, in comparison to LFAMs, when the minimum of the safety factor (qmin) deviates from a rational number. Meanwhile, the BAE eigenfunction peaks at the radial position of the maximum energetic particle pressure gradient, resulting in a large deviation from the qmin surface. The ascending frequency spectrum patterns of the experimentally observed BAEs and LFAMs can be theoretically reproduced by varying qmin and also be well interpreted based on the GFLDR. In particular, it is confirmed that the stability of the BAAE is not affected by energetic ions, which is consistent with the first-principle-based theory predictions and simulation results. The present analysis illustrates the solid predictive capability of the GFLDR and its practical usefulness in enhancing the interpretative capability of both experimental and numerical simulation results.

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反剪切托卡马克等离子体中低频剪切alfvsamn波的理论研究

动态热离子间隙频率范围内的低频alfv杂散波动由于能与热粒子和高能粒子相互作用而引起了研究的兴趣。本文在广义鱼骨样色散关系(GFLDR)的理论框架下，从理论上研究了托卡马克反磁剪切实验中观察到的高能和/或热粒子激发的低频剪切alfv录影带波的线性波特性。由于这些低频剪切alfv录影带波与2019年在DIII-D上进行的高能离子驱动低频不稳定性的专用实验密切相关，因此本文采用DIII-D具有代表性的实验平衡参数，证明实验观测到的低频模态和β诱导的alfv录影带本征模态(BAEs)分别是以alfv录影带极化为主的反应型和耗散型不稳定模态。因此，前者更准确地被称为低频alfvsamn模式(lfam)。更具体地说，由于抗磁性和捕获粒子效应，LFAM可以在低频区域(频率远低于热离子传输和/或反弹频率)与β诱导的alfv声学模式(BAAE)耦合;或与BAE在高频区域(频率高于或与热离子过境频率相当);导致反应型不稳定。此外，由于不稳定机制的不同，与lfam相比，BAEs的最大驱动发生在安全系数(qmin)的最小值偏离有理数时。同时，BAE特征函数在高能粒子压力梯度最大的径向位置达到峰值，与qmin表面偏差较大。实验观测到的BAEs和lfam的上升频谱模式可以通过改变qmin在理论上再现，并且基于GFLDR也可以很好地解释。特别是，证实了BAAE的稳定性不受高能离子的影响，这与基于第一性原理的理论预测和模拟结果是一致的。本文的分析说明了GFLDR的可靠预测能力及其在提高实验和数值模拟结果的解释能力方面的实际用途。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

物理学报物理-物理：综合

CiteScore

1.70

自引率

30.00%

发文量

31245

审稿时长

1.9 months

期刊介绍： Acta Physica Sinica (Acta Phys. Sin.) is supervised by Chinese Academy of Sciences and sponsored by Chinese Physical Society and Institute of Physics, Chinese Academy of Sciences. Published by Chinese Physical Society and launched in 1933, it is a semimonthly journal with about 40 articles per issue. It publishes original and top quality research papers, rapid communications and reviews in all branches of physics in Chinese. Acta Phys. Sin. enjoys high reputation among Chinese physics journals and plays a key role in bridging China and rest of the world in physics research. Specific areas of interest include: Condensed matter and materials physics; Atomic, molecular, and optical physics; Statistical, nonlinear, and soft matter physics; Plasma physics; Interdisciplinary physics.