A Balestri, J Ball, S Coda, D J Cruz-Zabala, M Garcia-Munoz and E Viezzer
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引用次数: 0
摘要
在这项工作中,我们研究了长宽比(主要半径 R0 与次要半径 r 之比)对负三角形(NT)等离子体整形的约束效益的影响。我们使用高保真通量管陀螺动能 GENE 仿真,并考虑了几种不同的情况:其中四种情况受到 TCV 实验数据的启发,一种情况受到 DIII-D 实验数据的启发,还有一种情况预计会出现在新的 SMART 球形托卡马克中。本研究揭示了一种明显的非三维依赖关系。对于 ITG 湍流,NT 在任何 A 值下都能提高约束性,而对于 TEM 湍流,只有在大纵横比和常规纵横比的情况下才能提高约束性。此外,通过对纯 ITG 驱动的大纵横比情况的详细研究,我们得出了一个直观的物理图景,解释了 NT 在大纵横比和常规纵横比情况下的有利影响。在以 TEM 为主导的情况下,这种图景并不成立,在这种情况下,许多因素会产生复杂的协同效应。最后,我们首次对 SMART 进行了线性陀螺动力学模拟,结果发现,NT 和 PT 两种情况都以微撕裂模式(MTM)湍流为主,而在狭长比情况下,NT 更容易受到 MTM 的影响。不过,在 SMART 中可以发现 ITG 占主导地位的情况,在这种情况下,NT 的线性稳定性更高。
Physical insights from the aspect ratio dependence of turbulence in negative triangularity plasmas
In this work, we study the impact of aspect ratio (the ratio of major radius R0 to minor radius r) on the confinement benefits of negative triangularity (NT) plasma shaping. We use high-fidelity flux tube gyrokinetic GENE simulations and consider several different scenarios: four of them inspired by TCV experimental data, a scenario inspired by DIII-D experimental data and a scenario expected in the new SMART spherical tokamak. The present study reveals a distinct and non-trivial dependence. NT improves confinement at any value of A for ITG turbulence, while for TEM turbulence confinement is improved only in the case of large and conventional aspect ratios. Additionally, through a detailed study of a large aspect ratio case with pure ITG drive, we develop an intuitive physical picture that explains the beneficial effect of NT at large and conventional aspect ratios. This picture does not hold in TEM-dominated regimes, where a complex synergistic effect of many factors is found. Finally, we performed the first linear gyrokinetic simulations of SMART, finding that both NT and PT scenarios are dominated by micro-tearing-mode (MTM) turbulence and that NT is more susceptible to MTMs at tight aspect ratio. However, a regime where ITG dominates can be found in SMART, and in this regime NT is more linearly stable.
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.