Nonlinear Dynamics and Auroral Acceleration Processes of Electrons Driven by Kinetic Alfvén Waves in the Magnetosphere

IF 2.6 2区地球科学 Q2 ASTRONOMY & ASTROPHYSICS

Journal of Geophysical Research: Space Physics Pub Date : 2025-03-16 DOI:10.1029/2024JA033469

Koseki Saito, Yuto Katoh, Yohei Kawazura, Atsushi Kumamoto

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Abstract

This study investigates the nonlinear Landau resonance and auroral acceleration processes of electrons driven by kinetic Alfvén waves (KAWs) in the Earth's magnetosphere. We analyze electron trajectories and parameters, such as kinetic energy, using test particle simulations, focusing on the transition between phase-trapped and phase-scattered states induced by magnetic field gradients. Based on the second-order resonance theory, we define the conditions under which electrons are either trapped or non-trapped by the KAWs. Our key findings are: (a) Electrons can be significantly accelerated not only when they are trapped by the waves and transported toward the ionosphere, but also in the detrapped state; (b) Even with monochromatic KAWs, the energy of electrons in the ionosphere depends on their state at the moment they are detrapped from the KAWs; (c) The dynamics of phase-scattered electrons affect the efficiency of electron acceleration processes.

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磁层中动力学alfvsamn波驱动电子的非线性动力学和极光加速过程

本文研究了地球磁层中由动力学alfv波浪（kaw）驱动的电子的非线性朗道共振和极光加速过程。我们使用测试粒子模拟分析了电子轨迹和参数，如动能，重点研究了磁场梯度诱导的相捕获态和相散射态之间的转变。基于二阶共振理论，我们定义了电子被kaw捕获或不被kaw捕获的条件。我们的主要发现是：(a)电子不仅在被波捕获并向电离层传输时，而且在脱扣状态下都可以显著加速；(b)即使是单色kaw，电离层中电子的能量也取决于它们脱离kaw时的状态；(c)相散射电子的动力学影响电子加速过程的效率。

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来源期刊

Journal of Geophysical Research: Space Physics Earth and Planetary Sciences-Geophysics

CiteScore

5.30

自引率

35.70%

发文量

570