Behavior of compressed plasmas in magnetic fields.

Reviews of modern plasma physics Pub Date : 2020-01-01 Epub Date: 2020-11-26 DOI:10.1007/s41614-020-00048-4
Gurudas Ganguli, Chris Crabtree, Alex Fletcher, Bill Amatucci
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引用次数: 4

Abstract

Plasma in the earth's magnetosphere is subjected to compression during geomagnetically active periods and relaxation in subsequent quiet times. Repeated compression and relaxation is the origin of much of the plasma dynamics and intermittency in the near-earth environment. An observable manifestation of compression is the thinning of the plasma sheet resulting in magnetic reconnection when the solar wind mass, energy, and momentum floods into the magnetosphere culminating in the spectacular auroral display. This phenomenon is rich in physics at all scale sizes, which are causally interconnected. This poses a formidable challenge in accurately modeling the physics. The large-scale processes are fluid-like and are reasonably well captured in the global magnetohydrodynamic (MHD) models, but those in the smaller scales responsible for dissipation and relaxation that feed back to the larger scale dynamics are often in the kinetic regime. The self-consistent generation of the small-scale processes and their feedback to the global plasma dynamics remains to be fully explored. Plasma compression can lead to the generation of electromagnetic fields that distort the particle orbits and introduce new features beyond the purview of the MHD framework, such as ambipolar electric fields, unequal plasma drifts and currents among species, strong spatial and velocity gradients in gyroscale layers separating plasmas of different characteristics, etc. These boundary layers are regions of intense activity characterized by emissions that are measurable. We study the behavior of such compressed plasmas and discuss the relaxation mechanisms to understand their measurable signatures as well as their feedback to influence the global scale plasma evolution.

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压缩等离子体在磁场中的行为。
地球磁层中的等离子体在地磁活跃期受到压缩,在随后的平静期受到松弛。在近地环境中,反复的压缩和弛豫是许多等离子体动力学和间歇性的起源。压缩的一个可观察到的表现是,当太阳风的质量、能量和动量涌入磁层时,等离子体层变薄,导致磁重联,最终形成壮观的极光。这种现象在所有尺度上都是丰富的物理现象,它们是因果关联的。这对精确地模拟物理过程提出了巨大的挑战。大尺度过程是流体状的,在全球磁流体动力学(MHD)模型中可以很好地捕捉到,但那些在较小尺度上负责耗散和松弛的过程,反馈到更大尺度动力学中,通常处于动力学状态。小规模过程的自洽产生及其对全球等离子体动力学的反馈仍有待充分探索。等离子体压缩会导致产生扭曲粒子轨道的电磁场,并引入超出MHD框架范围的新特征,如双极电场、种间不均匀的等离子体漂移和电流、分离不同特征等离子体的陀螺仪层中强大的空间和速度梯度等。这些边界层是活动强烈的区域,其特征是可测量的排放。我们研究了这种压缩等离子体的行为,并讨论了弛豫机制,以了解它们的可测量特征以及它们的反馈对全球尺度等离子体演化的影响。
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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