电子对 10 瞬间多流体模拟中并行质子火管不稳定性的影响

arXiv - PHYS - Plasma Physics Pub Date : 2024-08-08 DOI:arxiv-2408.04788

Jada Walters, Kristopher G. Klein, Emily Lichko, James Juno, Jason M. TenBarge

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引用次数: 0

摘要

压力各向异性驱动的不稳定性在调节空间和天体物理等离子体的能量传递方面起着至关重要的作用。我们首次使用多流体模型模拟了平行质子火喉不稳定性的演化和饱和，而不添加人工粘度。这些模拟是利用高质子-电子等离子体中具有局部和梯度弛豫热流闭合的10阶矩多流体模型进行的。当包括这些高阶时刻并允许在所有物质中形成压力各向异性时，我们发现电子对平行质子火喉不稳定性的饱和有重大影响，质子压力各向异性会随着不稳定性的饱和而改变。即使对于与日光层等离子体更相关的较低的（β），我们也能在使用梯度弛豫闭合的模拟中观察到明显的电子能化。我们的结果表明，解决电子压力各向异性问题对于正确描述多物种等离子体系统的行为非常重要。

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Electron Influence on the Parallel Proton Firehose Instability in 10-Moment, Multi-Fluid Simulations

Instabilities driven by pressure anisotropy play a critical role in modulating the energy transfer in space and astrophysical plasmas. For the first time, we simulate the evolution and saturation of the parallel proton firehose instability using a multi-fluid model without adding artificial viscosity. These simulations are performed using a 10-moment, multi-fluid model with local and gradient relaxation heat-flux closures in high-$\beta$ proton-electron plasmas. When these higher-order moments are included and pressure anisotropy is permitted to develop in all species, we find that the electrons have a significant impact on the saturation of the parallel proton firehose instability, modulating the proton pressure anisotropy as the instability saturates. Even for lower $\beta$s more relevant to heliospheric plasmas, we observe a pronounced electron energization in simulations using the gradient relaxation closure. Our results indicate that resolving the electron pressure anisotropy is important to correctly describe the behavior of multi-species plasma systems.

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arXiv - PHYS - Plasma Physics

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