Transverse instability of electron-acoustic solitons in a relativistic degenerate astrophysical magnetoplasma

arXiv - PHYS - Plasma Physics Pub Date : 2024-08-08 DOI:arxiv-2408.04404

A. P. Misra, A. Abdikian

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Abstract

We study the nonlinear theory of small-amplitude electron-acoustic solitons (EASs) in a relativistic astrophysical magnetoplasma consisting of two-temperature electrons: a sparse population of relativistic nondegenerate classical electrons and a group of fully degenerate dense relativistic electrons (main constituent) immersed in a static magnetic field with a neutralizing stationary ion background. By using the multiple-scale reductive perturbation technique with the Lorentz transformation, the Zakharov-Kuznetsov (ZK) and the modified Zakharov-Kuznetsov (mZK) equations are derived to describe the evolution of EASs in two different regimes of relativistic degeneracy: $r_{d0}<50$ and $r_{d0}\gtrsim50$. The characteristics of the plane soliton solutions of ZK and mZK equations and the soliton energy are studied. We show that the solitons moving at an angle $\alpha$ to the external magnetic field can be unstable under transverse long-wavelength perturbations. The growth rates of instabilities are obtained and analyzed with the effects of the relativity parameter $\beta_{\rm{cl}}=k_BT_{\rm{cl}}/m_ec^2$ and the degeneracy parameter $r_{d0}$, where $k_B$ is the Boltzmann constant and $T_{\rm{cl}}$ is the temperature of classical electrons. Interestingly, the ZK solitons, even if it is stable for the first-order perturbations, can be unstable in the second-order correction. Furthermore, while the first-order growth rates of perturbations for ZK solitons tend to vanish as $\alpha\rightarrow 38^\circ$, that for the mZK soliton goes to zero as $\alpha\rightarrow 90^\circ$. However, depending on the angle $\alpha$, the growth rates are found to be reduced either by increasing the values of $\beta_{\rm{cl}}$ or by decreasing the values of $r_{d0}$. The applications of our results to astrophysical plasmas, such as those in the environments of white dwarfs are discussed.

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相对论退化天体物理磁等离子体中电子声孤子的横向不稳定性

我们研究了相对论天体物理磁等离子体中的小振幅电子声孤子（EASs）的非线性理论，该等离子体由两种温度的电子组成：一个稀疏的相对论非变性经典电子群和一组完全变性的致密相对论电子（主要成分），它们浸没在一个具有中和静态离子背景的静态磁场中。通过使用洛伦兹变换的多尺度还原扰动技术，推导出了扎哈罗夫-库兹涅佐夫（ZK）方程和修正的扎哈罗夫-库兹涅佐夫（mZK）方程，以描述EAS在两种不同的相对退化状态下的演化：$r_{d0}<50$和$r_{d0}\gtrsim50$。我们研究了ZK方程和mZK方程的平面孤子解的特征以及孤子能量。我们发现，与外磁场成$\alpha$角运动的孤子在横向长波扰动下是不稳定的。我们得到了不稳定性的增长率，并分析了不稳定性参数$\beta_{\rm{cl}}=k_BT_{\rm{cl}}/m_ec^2$和变性参数$r_{d0}$的影响，其中$k_B$是玻尔兹曼常数，$T_{\rm{cl}}$是经典电子的温度。有趣的是，ZK 孤子即使在一阶扰动下是稳定的，在二阶修正时也可能是不稳定的。此外，虽然ZK孤子的一阶扰动增长率在$\alpha\rightarrow 38^\circ$时趋于消失，但mZK孤子的一阶扰动增长率在$\alpha\rightarrow 90^\circ$时趋于零。然而，根据角度 $\alpha$ 的不同，我们发现增长速率会通过增加 $\beta_{\rm{cl}}$ 的值或减少 $r_{d0}$ 的值而降低。讨论了我们的结果在天体物理等离子体（如白矮星环境中的等离子体）中的应用。

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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arXiv - PHYS - Plasma Physics

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