Nonlinear turbulent transport in magnetic fusion plasmas

Computational science & discovery Pub Date : 2008-10-01 DOI:10.1088/1749-4699/1/1/015010

W. Lee, S. Ethier, R. Kolesnikov, W. Wang, W. Tang

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引用次数: 9

Abstract

For more than a decade, the study of microturbulence driven by ion temperature gradient (ITG) drift instabilities in tokamak devices has been an active area of research in magnetic fusion science for both experimentalists and theorists alike. An important impetus for this avenue of research was the discovery of the radial streamers associated with the ITG modes in the early 1990s using the particle-in-cell (PIC) simulation method. Subsequently, ITG simulations using codes with increasing realism have been made possible by the dramatic increase in computing power. Notable examples were the demonstration of the importance of nonlinearly generated zonal flows in regulating ion thermal transport and the transition from Bohm to gyroBohm scaling with increased device size. In this paper, we will describe an interesting nonlinear physical process, as well as the resulting turbulent transport, that is associated with the interactions between the nonlinear parallel acceleration of the ions and the zonal flow modes. This study was carried out by utilizing a fully parallelized three-dimensional PIC code in global toroidal geometry on the most advanced, modern, massively parallel supercomputers.

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磁融合等离子体中的非线性湍流输运

十多年来，托卡马克装置中离子温度梯度(ITG)漂移不稳定性驱动的微湍流研究一直是磁聚变科学中实验家和理论家的一个活跃研究领域。这一研究途径的一个重要推动力是，在20世纪90年代初，使用粒子池(PIC)模拟方法发现了与ITG模式相关的径向流。随后，由于计算能力的急剧提高，使用越来越逼真的代码进行ITG模拟成为可能。值得注意的例子是，非线性产生的纬向流在调节离子热输运中的重要性，以及随着设备尺寸的增加，从Bohm尺度向gyroBohm尺度的转变。在本文中，我们将描述一个有趣的非线性物理过程，以及由此产生的湍流输运，这与离子的非线性平行加速度和纬向流动模式之间的相互作用有关。这项研究是在最先进的现代大规模并行超级计算机上利用全并行化的三维PIC代码在全局环面几何中进行的。

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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Computational science & discovery

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