Effects of Superthermal Plasmas on Hiss Wave-Driven Scattering Loss of Radiation Belt Electrons

IF 2.6 2区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS Journal of Geophysical Research: Space Physics Pub Date : 2024-09-29 DOI:10.1029/2024JA032808
Xin Ma, Qi Zhu, Yuequn Lou, Xing Cao, Binbin Ni, Shuqin Chen, Taifeng Jin
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Abstract

Plasmaspheric hiss plays an important role in the loss of radiation belt electrons via cyclotron resonant interactions. The cold plasma approximation is widely used in the evaluation of hiss-driven electron losses, which however can break down during disturbed periods of geomagnetic storms and substorms. The kappa particle velocity distribution, characterized by a pronounced high-energy tail, is well-established to model the profile of superthermal plasma under disturbed geomagnetic conditions. In the present study, by calculating the electron bounce-averaged pitch angle diffusion coefficients with kappa plasma dispersion relations, we investigate the sensitivity of hiss-induced cyclotron-resonant electron scattering loss to the spectral index κ under a variety of superthermal plasma conditions. Our results demonstrate that, with increasing κ, the diffusion coefficients of ∼20–100 keV radiation belt electrons significantly decrease at lower pitch angles and increase at higher pitch angles. In contrast, for electrons at higher energies, the diffusion coefficients tend to increase at lower pitch angles and decrease at relatively higher pitch angles. We also find that decrease of L-shell and increase of α* and temperature anisotropy tend to weaken the hiss-driven pitch angle scattering efficiency of electrons at energies from tens to hundreds of keV with a dip at ∼30–50 keV, while the scattering of higher energy electrons can be enhanced. This study confirms the important role of superthermal plasmas in the hiss-driven electron loss processes and should be carefully incorporated in future modeling of radiation belt electron dynamics.

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超热等离子体对咝声波驱动的辐射带电子散射损耗的影响
等离子体嘶嘶声在通过回旋共振相互作用损失辐射带电子方面发挥着重要作用。冷等离子体近似法被广泛用于评估嘶嘶声驱动的电子损耗,但在地磁暴和亚暴的扰动期,这种近似法可能会失效。卡帕粒子速度分布具有明显的高能量尾部特征,可用于模拟地磁扰动条件下的超热等离子体剖面。在本研究中,通过利用卡帕等离子体弥散关系计算电子反弹平均俯仰角扩散系数,我们研究了在各种超热等离子体条件下,嘶嘶声诱导的回旋共振电子散射损耗对光谱指数κ的敏感性。我们的研究结果表明,随着κ的增大,∼20-100 keV辐射带电子的扩散系数在低俯仰角时显著减小,而在高俯仰角时则显著增大。相反,对于能量较高的电子,扩散系数在俯仰角较低时趋于增大,而在俯仰角相对较大时则趋于减小。我们还发现,L-shell 的减小、α* 和温度各向异性的增大往往会削弱嘶嘶声驱动的电子在几十到几百千伏的能量范围内的俯仰角散射效率,并在∼30-50 千伏时出现下降,而高能量电子的散射则会增强。这项研究证实了超热等离子体在嘶嘶声驱动的电子损耗过程中的重要作用,应将其仔细纳入未来的辐射带电子动力学建模中。
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来源期刊
Journal of Geophysical Research: Space Physics
Journal of Geophysical Research: Space Physics Earth and Planetary Sciences-Geophysics
CiteScore
5.30
自引率
35.70%
发文量
570
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