150 至 20,000 公里全向高能电子通量:基于 ELFIN 的模型

IF 2.6 2区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS
Emile Saint-Girons, Xiao-Jia Zhang, Didier Mourenas, Anton V. Artemyev, Vassilis Angelopoulos
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引用次数: 0

摘要

地球内磁层高能电子通量的强烈变化是众所周知的难以预测。因此,建立从低到高各个纬度的电子通量的精确经验模型,对于提高我们对通量变化的理解和评估航天器系统的辐射危害非常有用。在本研究中,利用绝热传输理论和准线性扩散理论,利用电子损耗和场调查(ELFIN)立方体卫星在低空测量到的能量和俯仰角分辨沉淀、捕获和反向散射电子通量,推断出航天器下方和上方高度(150 至 20,000 公里)的全向通量。利用逐步多元优化程序将推断出的通量拟合为所选参数的函数,根据仅从低地球轨道上的一个航天器测得的数据,提供了沿每条地磁场线的全向电子通量的分析模型。模型中的电子通量是 L $L$ -shell、高度、能量和过去亚暴活动的两个不同指数的函数,这些指数是在过去 4 小时或 3 天内计算得出的,有可能将脉冲过程(如快速注入)与累积过程(如向内径向扩散和波驱动的能量化)区分开来。通过与范艾伦探测器的赤道测量结果进行比较,对模型进行了验证,证明了本方法的广泛适用性。该模型表明,脉冲和时间整合亚暴活动在一定程度上控制着外辐射带和等离子体片的电子通量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Omnidirectional Energetic Electron Fluxes From 150 to 20,000 km: An ELFIN-Based Model

The strong variations of energetic electron fluxes in the Earth's inner magnetosphere are notoriously hard to forecast. Developing accurate empirical models of electron fluxes from low to high altitudes at all latitudes is therefore useful to improve our understanding of flux variations and to assess radiation hazards for spacecraft systems. In the present work, energy- and pitch-angle-resolved precipitating, trapped, and backscattered electron fluxes measured at low altitude by Electron Loss and Fields Investigation (ELFIN) CubeSats are used to infer omnidirectional fluxes at altitudes below and above the spacecraft, from 150 to 20,000 km, making use of adiabatic transport theory and quasi-linear diffusion theory. The inferred fluxes are fitted as a function of selected parameters using a stepwise multivariate optimization procedure, providing an analytical model of omnidirectional electron flux along each geomagnetic field line, based on measurements from only one spacecraft in low Earth orbit. The modeled electron fluxes are provided as a function of L $L$ -shell, altitude, energy, and two different indices of past substorm activity, computed over the preceding 4 hr or 3 days, potentially allowing to disentangle impulsive processes (such as rapid injections) from cumulative processes (such as inward radial diffusion and wave-driven energization). The model is validated through comparisons with equatorial measurements from the Van Allen Probes, demonstrating the broad applicability of the present method. The model indicates that both impulsive and time-integrated substorm activity partly control electron fluxes in the outer radiation belt and in the plasma sheet.

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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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