Plasma wave propagation conditions analysis using the warm multi-fluid model

Fundamental Plasma Physics Pub Date : 2024-04-26 DOI:10.1016/j.fpp.2024.100050

Huasheng Xie , Haojie Ma , Yukun Bai

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Abstract

Although an accurate description of wave propagation and absorption in plasmas requires complicated full-wave solutions or kinetic simulations, local dispersion analysis can still be helpful to capture the main physics of wave properties. Plasma wave propagation conditions or accessibility informs whether a wave can propagate to a region, which usually depends on the wave frequency, wave vector, the local plasma density, and magnetic field. We demonstrate a warm multi-fluid eigenvalue model and a matrix approach to rapidly calculate plasma wave accessibility diagrams, where thermal effects are also included via an isotropic pressure term. All cold plasma waves, from high-frequency electron cyclotron waves, intermediate-frequency lower hybrid waves, to low-frequency ion cyclotron waves, are presented. By comparing with the kinetic model, it is interesting to find that the warm multi-fluid model, though incapable of reproducing the Bernstein modes, can provide a quick way to determine whether thermal effects are important.

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利用暖多流体模型分析等离子体波的传播条件

尽管准确描述等离子体中的波传播和吸收需要复杂的全波求解或动力学模拟，但局部频散分析仍有助于捕捉波特性的主要物理特性。等离子体波的传播条件或可及性告诉我们波是否能传播到某个区域，这通常取决于波的频率、波矢量、局部等离子体密度和磁场。我们展示了一个温暖的多流体特征值模型和一种矩阵方法，用于快速计算等离子体波的可达性图，其中热效应也通过各向同性压力项包括在内。所有冷等离子体波，从高频电子回旋波、中频低混合波到低频离子回旋波，都一一呈现。通过与动力学模型的比较，我们发现暖多流体模型虽然无法再现伯恩斯坦模式，但却可以快速确定热效应是否重要。

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Fundamental Plasma Physics

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