关于无碰撞冲击下游超阿尔夫尼科流的形成

Adnane Osmane and Savvas Raptis
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引用次数: 0

摘要

在高贝塔和低贝塔等离子体条件下,地球弓形冲击的下游通常会产生动能密度大大超过太阳风的超阿尔费尼喷流。在这项研究中,我们提出了理论证据,证明这些增强的动能流可以由无碰撞等离子体环境中的火管不稳定波动和压缩加热驱动。利用包含压力各向异性的流体形式主义,我们估计在火管不稳定性压缩和饱和之后,无碰撞等离子体冲击的下游流可以加速 2-4 倍。通过分析磁层多尺度(MMS)任务现场观测到的准平行磁鞘喷流,我们发现在这些喷流中约有11%的等离子体测量值呈现出火管不稳定性波动。我们的发现为低(β < 1)和高(β > 1)β等离子体中快速下行流的独特产生提供了解释,并提供了新的证据,证明动力学过程对于准确描述磁鞘射流的形成和演化至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
On the Formation of Super-Alfvénic Flows Downstream of Collisionless Shocks
Super-Alfvénic jets, with kinetic energy densities significantly exceeding that of the solar wind, are commonly generated downstream of Earth's bow shock under both high- and low-beta plasma conditions. In this study, we present theoretical evidence that these enhanced kinetic energy flows can be driven by firehose-unstable fluctuations and compressive heating within collisionless plasma environments. Using a fluid formalism that incorporates pressure anisotropy, we estimate that the downstream flow of a collisionless plasma shock can be accelerated by a factor of 2–4 following the compression and saturation of firehose instability. By analyzing quasi-parallel magnetosheath jets observed in situ by the Magnetospheric Multiscale (MMS) mission, we find that approximately 11% of plasma measurements within these jets exhibit firehose-unstable fluctuations. Our findings offer an explanation for the distinctive generation of fast downstream flows in both low (β < 1) and high (β > 1) beta plasmas, and provide new evidence that kinetic processes are crucial for accurately describing the formation and evolution of magnetosheath jets.
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