The Interplay Between Collisionless Magnetic Reconnection and Turbulence

arXiv - PHYS - Space Physics Pub Date : 2024-07-30 DOI:arxiv-2407.20787

J. E. Stawarz, P. A. Muñoz, N. Bessho, R. Bandyopadhyay, T. K. M. Nakamura, S. Eriksson, D. Graham, J. Büchner, A. Chasapis, J. F. Drake, M. A. Shay, R. E. Ergun, H. Hasegawa, Yu. V. Khotyaintsev, M. Swisdak, F. Wilder

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Abstract

Alongside magnetic reconnection, turbulence is another fundamental nonlinear plasma phenomenon that plays a key role in energy transport and conversion in space and astrophysical plasmas. From a numerical, theoretical, and observational point of view there is a long history of exploring the interplay between these two phenomena in space plasma environments; however, recent high-resolution, multi-spacecraft observations have ushered in a new era of understanding this complex topic. The interplay between reconnection and turbulence is both complex and multifaceted, and can be viewed through a number of different interrelated lenses - including turbulence acting to generate current sheets that undergo magnetic reconnection (turbulence-driven reconnection), magnetic reconnection driving turbulent dynamics in an environment (reconnection-driven turbulence) or acting as an intermediate step in the excitation of turbulence, and the random diffusive/dispersive nature of magnetic field lines embedded in turbulent fluctuations enabling so-called stochastic reconnection. In this paper, we review the current state of knowledge on these different facets of the interplay between turbulence and reconnection in the context of collisionless plasmas, such as those found in many near-Earth astrophysical environments, from a theoretical, numerical, and observational perspective. Particular focus is given to several key regions in Earth's magnetosphere - Earth's magnetosheath, magnetotail, and Kelvin-Helmholtz vortices on the magnetopause flanks - where NASA's Magnetospheric Multiscale mission has been providing new insights on the topic.

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无碰撞磁重连接与湍流之间的相互作用

除了磁重联之外，湍流是另一种基本的非线性等离子体现象，在激发空间和天体物理等离子体的能量传输和转换中发挥着关键作用。从数值、理论和观测的角度来看，探索空间等离子体环境中这两种现象之间的相互作用由来已久；然而，最近的高分辨率多航天器观测开创了了解这一复杂课题的新时代。重连接与湍流之间的相互作用既复杂又多面，可以通过一些不同的相互关联的视角来观察--包括湍流作用于产生发生磁性重连接的电流片（湍流驱动的重连接）、磁性重连接驱动环境中的湍流动力学（重连接驱动的湍流）或作为激发湍流的中间步骤，以及嵌入湍流波动中的磁场线的随机扩散/分散性质促成了所谓的随机重连接。在本文中，我们从理论、数值和观测的角度回顾了在无碰撞等离子体（如在许多近地天体物理环境中发现的等离子体）中湍流与重连接之间相互作用的这些不同方面的知识现状。特别侧重于地球磁层的几个关键区域--地球磁鞘、磁尾和磁极侧的开尔文-赫尔姆霍兹涡旋--美国国家航空航天局的磁层多尺度任务一直在这些区域提供有关该主题的新见解。

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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arXiv - PHYS - Space Physics

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