Global gyrokinetic study of density gradient driven instability in tokamaks: the ubiquitous mode

IF 2.1 2区 物理与天体物理 Q2 PHYSICS, FLUIDS & PLASMAS
Sagar Choudhary, Jugal Chowdhury, Gopal Krishna M, Jagannath Mahapatra, Amit K Singh, Rajaraman Ganesh and Laurent Villard
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Abstract

The ubiquitous mode is investigated in the linear regime for the first time using a global gyrokinetic model. These modes are driven by the density gradient in trapped electron population but with mode frequency in the ion diamagnetic drift direction, in contrast to the conventional trapped electron mode. The dispersion relation is calculated along with the global mode structure. The ubiquitous mode is quite global although appears at a shorter wavelength ( ). We show that the main driving mechanism is the density gradient and the temperature gradient has only a modest effect; the mode can persist at higher temperature gradient scenarios making it another possible channel of anomalous transport. The magnetic shear reduces the growth of the mode; while the electron to ion temperature ratio has a nonmonotonic effect on the mode growth rate—growth rate increases initially for the ubiquitous branch of the mode and decreases afterwards as the conventional trapped electron mode starts dominating. The role of safety factor and toroidicity is also analyzed. Finally, a mixing length-based estimation of transport is presented.
托卡马克密度梯度驱动不稳定性的全球陀螺动力学研究:无处不在的模式
利用全局陀螺动力学模型首次研究了线性机制中的无处不在模式。这些模式受困电子群密度梯度的驱动,但模式频率在离子二磁漂移方向上,这与传统的困电子模式不同。在计算频散关系的同时还计算了全局模式结构。无处不在的模式虽然出现在较短的波长( )上,但却具有很强的全局性。我们的研究表明,主要的驱动机制是密度梯度,而温度梯度的影响不大;该模式可以在温度梯度较高的情况下持续存在,从而使其成为另一种可能的反常传输通道。磁剪切降低了模式的增长速度;而电子与离子温度比对模式增长速度的影响是非单调的--模式的无处不在分支的增长速度最初会增加,之后随着传统的俘获电子模式开始占主导地位,增长速度会降低。此外,还分析了安全系数和环性的作用。最后,介绍了基于混合长度的传输估算。
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来源期刊
Plasma Physics and Controlled Fusion
Plasma Physics and Controlled Fusion 物理-物理:核物理
CiteScore
4.50
自引率
13.60%
发文量
224
审稿时长
4.5 months
期刊介绍: Plasma Physics and Controlled Fusion covers all aspects of the physics of hot, highly ionised plasmas. This includes results of current experimental and theoretical research on all aspects of the physics of high-temperature plasmas and of controlled nuclear fusion, including the basic phenomena in highly-ionised gases in the laboratory, in the ionosphere and in space, in magnetic-confinement and inertial-confinement fusion as well as related diagnostic methods. Papers with a technological emphasis, for example in such topics as plasma control, fusion technology and diagnostics, are welcomed when the plasma physics is an integral part of the paper or when the technology is unique to plasma applications or new to the field of plasma physics. Papers on dusty plasma physics are welcome when there is a clear relevance to fusion.
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