大尺度磁重联过程中质子和电子的同时激发

arXiv - PHYS - Space Physics Pub Date : 2024-07-15 DOI:arxiv-2407.10933

Zhiyu Yin, James F. Drake, Marc Swisdak

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摘要

本文介绍了在宏观尺度系统中伴随电子和质子加热和赋能的磁重联模拟结果。两种粒子都形成了扩展的幂律分布，能量扩展了近三十年。这些非热粒子产生的主要驱动机制是在不断演化和凝聚的磁通量漩涡中的费米反射。虽然两种粒子的幂律指数相当，但质子总体上比电子获得了更多的能量，其幂律也延伸到了更高的能量。幂律在低能量时滚动成热分布，与质子相比，电子的转换能量发生在较低的能量处。强导场通过减少费米驱动机制来减少非热粒子的产生。在太阳耀斑中，质子的功率定律应该延伸到 10's keV，远远低于可以通过伽马射线发射直接探测的能量。因此，质子携带的释放磁能应该比直接观测所预期的要多得多。

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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Simultaneous Proton and Electron Energization during Macroscale Magnetic Reconnection

The results of simulations of magnetic reconnection accompanied by electron and proton heating and energization in a macroscale system are presented. Both species form extended powerlaw distributions that extend nearly three decades in energy. The primary drive mechanism for the production of these nonthermal particles is Fermi reflection within evolving and coalescing magnetic flux ropes. While the powerlaw indices of the two species are comparable, the protons overall gain more energy than electrons and their power law extends to higher energy. The power laws roll into a hot thermal distribution at low energy with the transition energy occurring at lower energy for electrons compared with protons. A strong guide field diminishes the production of non-thermal particles by reducing the Fermi drive mechanism. In solar flares, proton power laws should extend down to 10's of keV, far below the energies that can be directly probed via gamma-ray emission. Thus, protons should carry much more of the released magnetic energy than expected from direct observations.

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arXiv - PHYS - Space Physics

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