Magnetic confinement for the 2D axisymmetric relativistic Vlasov-Maxwell system in an annulus

IF 1 4区数学 Q1 MATHEMATICS

Kinetic and Related Models Pub Date : 2021-11-08 DOI:10.3934/krm.2021039

Jin Woo Jang, Robert M. Strain, T. Wong

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引用次数: 2

Abstract

Although the nuclear fusion process has received a great deal of attention in recent years, the amount of mathematical analysis that supports the stability of the system seems to be relatively insufficient. This paper deals with the mathematical analysis of the magnetic confinement of the plasma via kinetic equations. We prove the global wellposedness of the Vlasov-Maxwell system in a two-dimensional annulus when a huge (but finite-in-time) external magnetic potential is imposed near the boundary. We assume that the solution is axisymmetric. The authors hope that this work is a step towards a more generalized work on the three-dimensional Tokamak structure. The highlight of this work is the physical assumptions on the external magnetic potential well which remains finite within a finite time interval and from that, we prove that the plasma never touches the boundary. In addition, we provide a sufficient condition on the magnitude of the external magnetic potential to guarantee that the plasma is confined in an annulus of the desired thickness which is slightly larger than the initial support. Our method uses the cylindrical coordinate forms of the Vlasov-Maxwell system.

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环空中二维轴对称相对论Vlasov-Maxwell系统的磁约束

尽管近年来核聚变过程受到了极大的关注，但支持该系统稳定性的数学分析数量似乎相对不足。本文用动力学方程对等离子体的磁约束进行了数学分析。我们证明了在二维环空边界附近施加巨大(但时间有限)的外磁势时，Vlasov-Maxwell系统的全局适定性。我们假设解是轴对称的。作者希望这项工作是朝着三维托卡马克结构更广泛的工作迈出的一步。本工作的重点是对外磁势阱在有限时间内保持有限的物理假设，并由此证明了等离子体不接触边界。此外，我们提供了外部磁势大小的充分条件，以保证等离子体被限制在比初始支撑略大的所需厚度的环空中。我们的方法使用了Vlasov-Maxwell系统的柱坐标形式。

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

Kinetic and Related Models 数学-数学

CiteScore

2.10

自引率

10.00%

发文量

审稿时长

>12 weeks

期刊介绍： KRM publishes high quality papers of original research in the areas of kinetic equations spanning from mathematical theory to numerical analysis, simulations and modelling. It includes studies on models arising from physics, engineering, finance, biology, human and social sciences, together with their related fields such as fluid models, interacting particle systems and quantum systems. A more detailed indication of its scope is given by the subject interests of the members of the Board of Editors. Invited expository articles are also published from time to time.