Electron precipitation caused by intense whistler-mode waves: combined effects of anomalous scattering and phase bunching

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Frontiers in Astronomy and Space Sciences Pub Date : 2023-12-22 DOI:10.3389/fspas.2023.1322934
L. Gan, Wen Li, Mirek Hanzelka, Qianli Ma, Jay M. Albert, Anton Artemyev
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Abstract

Resonant interactions with whistler-mode waves are a crucial mechanism that drives the precipitation of energetic electrons. Using test particle simulations, we investigated the impact of nonlinear interactions of whistler-mode waves on electron precipitation across a broad energy range (10 keV- 1 MeV). Specifically, we focused on the combined effects of conventional phase bunching and anomalous scattering, which includes anomalous trapping and positive bunching. It is shown that anomalous scattering transports electrons away from the loss cone and the only process directly causing precipitation in the nonlinear regime is the phase bunching. We further show that their combined effects result in a precipitation-to-trapped flux ratio lower than the quasilinear expectations in a quasi-equilibrium state. Additionally, we calculated the diffusion and advection coefficients associated with the nonlinear trapping and bunching processes, which are vital for understanding the underlying mechanisms of the precipitation. Based on these coefficients, we characterized the phase bunching boundary, representing the innermost pitch angle boundary where phase bunching can occur. A further analysis revealed that electrons just outside this boundary, rather than near the loss cone, are directly precipitated, while electrons within the boundary are prevented from precipitation due to anomalous scattering. Moreover, we demonstrated that the regime of dominant nonlinear precipitation is determined by the combination of the phase bunching boundary and the inhomogeneity ratio. This comprehensive analysis provides insights into the nonlinear effects of whistler-mode waves on electron precipitation, which are essential for understanding physical processes related to precipitation, such as microbursts, characterized by intense and bursty electron precipitation.
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强烈惠斯勒模式波引起的电子析出:异常散射和相位束化的综合效应
与惠斯勒模式波的共振相互作用是驱动高能电子析出的重要机制。通过测试粒子模拟,我们研究了惠斯勒模式波的非线性相互作用对宽能量范围(10 keV-1 MeV)内电子析出的影响。具体来说,我们重点研究了传统相束流和反常散射(包括反常陷波和正束流)的综合影响。结果表明,反常散射会将电子从损耗锥转移走,而在非线性机制中直接导致沉淀的唯一过程是相位束射。我们进一步证明,它们的共同作用导致在准平衡状态下,析出与俘获通量比低于准线性预期。此外,我们还计算了与非线性捕集和束集过程相关的扩散和平流系数,这对理解降水的基本机制至关重要。根据这些系数,我们确定了相束缚边界的特征,它代表了可能发生相束缚的最内侧俯仰角边界。进一步的分析表明,该边界外而非损耗锥附近的电子会直接析出,而边界内的电子则由于异常散射而无法析出。此外,我们还证明了非线性析出的主导机制是由相束缚边界和不均匀性比率共同决定的。这种全面的分析提供了关于啸模波对电子析出的非线性效应的见解,这对理解与析出有关的物理过程(如以强烈的迸发电子析出为特征的微暴)至关重要。
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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