双卡帕等离子体中alfv -回旋加速器不稳定性的标度

IF 2.9 3区 地球科学
YueQun Lou, Xing Cao, MingYu Wu, BinBin Ni, TieLong Zhang
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引用次数: 0

摘要

空间等离子体中的粒子速度分布通常表现出非麦克斯韦高能尾巴,可以很好地用kappa分布来模拟。在本研究中,我们着重研究了离子温度各向异性驱动的kappa等离子体中alfv回旋加速器不稳定性的增长率。通过求解动力学线性色散方程,我们探讨了在不同等离子体条件下,包括各种等离子体β \ β _hp和热质子的温度各向异性A_hp值,生长速率对bi-kappa分布光谱指数κ的敏感性。此外,导出了一个简明的解析标度公式,该公式将无量纲最大增长率与三个自变量:光谱指数、等离子体β和热质子的温度各向异性联系起来。结果表明,随着κ-值的增大,不稳定带宽变窄,最大增长率显著增大。对于较高的\beta _hp和A_hp,最大不稳定性也急剧增加。当我们将无因次最大增长率的拟合与动力学线性色散理论的解进行比较时,它们之间的结果通常表现出很好的一致性。特别是在大κ值和高β _hp和A_hp的情况下,最大增长率的标度主要准确地模拟了数值解。我们的解析表达式可以很容易地用于地球磁层的大尺度模型,以理解由于alfv回旋加速器不稳定性而产生的波。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Scalings for the Alfvén-cyclotron instability in a bi-kappa plasma
The particle velocity distribution in space plasma usually exhibits a non-Maxwellian high-energy tail that can be well modeled by kappa distributions. In this study, we focus on the growth rates of the Alfvén-cyclotron instability driven by ion temperature anisotropy in a kappa plasma. By solving the kinetic linear dispersion equation, we explore the sensitivity of growth rates to the spectral index κ of a bi-kappa distribution under different plasma conditions, including a variety of plasma beta \beta _hp and temperature anisotropy A_hp values of hot protons. Furthermore, a concise, analytic scaling formula is derived that relates the dimensionless maximum growth rate to three independent variables: the spectral index and the plasma beta and temperature anisotropy of hot protons. Our results show that as the κ-value increases, the instability bandwidth narrows and the maximum growth rate increases significantly. For higher \beta _hp and A_hp , the maximum instability undergoes a sharp increase as well. When our fits of dimensionless maximum growth rates are compared with solutions to kinetic linear dispersion theory, the results generally exhibit good agreement between them. Especially under the circumstances of large κ-values and high \beta _hp and A_hp , the scalings of maximum growth rates primarily accurately model the numerical solutions. Our analytic expressions can readily be used in large-scale models of the Earth’s magnetosphere to understand wave generation due to the Alfvén-cyclotron instability.
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来源期刊
Earth and Planetary Physics
Earth and Planetary Physics GEOSCIENCES, MULTIDISCIPLINARY-
自引率
17.20%
发文量
174
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