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地球外磁层中密集低能离子的调查:与太阳风动压、星际磁场和磁层活动的关系

A Survey of Dense Low Energy Ions in Earth's Outer Magnetosphere: Relation to Solar Wind Dynamic Pressure, IMF, and Magnetospheric Activity.

作者信息

Hull Arthur J, Agapitov Oleksiy, Mozer Forrest S, McFadden James P, Angelopoulos Vassilis

机构信息

Space Sciences Laboratory University of California, Berkeley Berkeley CA USA.

Earth, Planetary and Space Sciences Institute of Geophysics and Space Physics University of California, Los Angeles Los Angeles CA USA.

出版信息

J Geophys Res Space Phys. 2021 Sep;126(9):e2021JA029208. doi: 10.1029/2021JA029208. Epub 2021 Sep 3.

DOI:10.1029/2021JA029208
PMID:35865829
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9285958/
Abstract

The properties of cold, dense, low energy ( 150 eV) ions within Earth's magnetosphere between 6 and 14 distance are examined using data sampled by Time History of Events and Macroscale Interactions during Substorms spacecraft during a new low-energy plasma mode that operated from June 2016 to July 2017. These ions are a persistent feature of the magnetosphere during enhanced solar wind dynamic pressure and/or magnetospheric activity. These ions have densities ranging from 0.5 to tens of , with a mean of 1 and temperatures of a few to tens of eV, with a mean of 13 eV. These yield cold to hot ion density and temperature ratios that are 4.4 and , respectively. Comparisons reveal that the cold ion densities are positively correlated with solar wind dynamic pressure. These ions are organizable, according to their pitch-angle distribution, as being transverse/convection dominated (interpreted as plume plasma) or magnetic field-aligned (FAL) (uni- or bi-directional characteristic of ion outflow or cloak plasma). Transverse ions preferentially occur in the prenoon to dusk sectors during sustained active magnetospheric conditions driven by enhanced solar wind dynamic pressure under southward and westward IMF orientations. Transverse ion velocities (reaching several tens of km/s) have a westward directed tendency with a slight radially outward preference. In contrast FAL ions preferentially occur from morning to noon during northward IMF orientations, enhanced solar wind dynamic pressure, and quiet magnetospheric conditions within several hours after moderate to strong activity. The FAL ions also have bulk velocities 30 km/s, with an eastward and radially outward tendency.

摘要

利用“亚暴期间事件和宏观相互作用时间历程”(Time History of Events and Macroscale Interactions during Substorms,THEMIS)航天器在2016年6月至2017年7月运行的一种新的低能等离子体模式下采样的数据,研究了地球磁层中距离在6至14个地球半径之间冷、密、低能(150电子伏特)离子的特性。这些离子是增强太阳风动压和/或磁层活动期间磁层的一个持续特征。这些离子的密度范围为0.5至数十个每立方厘米,平均密度为1个每立方厘米,温度为几电子伏特至几十电子伏特,平均温度为13电子伏特。这些离子产生的冷离子与热离子密度比和温度比分别为4.4和[此处原文缺失具体数值]。比较结果表明,冷离子密度与太阳风动压呈正相关。根据其俯仰角分布,这些离子可分为横向/对流主导(解释为羽流等离子体)或磁场对齐(FAL)(离子流出或隐身等离子体的单向或双向特征)。在南向和西向的行星际磁场(IMF)取向以及增强的太阳风动压驱动的持续活跃磁层条件下,横向离子优先出现在午前至黄昏扇区。横向离子速度(可达几十千米每秒)有向西的趋势,且略有径向向外的偏好。相比之下,在北向IMF取向、增强的太阳风动压以及中等到强烈活动后数小时内的安静磁层条件下,FAL离子优先出现在早晨至中午。FAL离子的整体速度也大于30千米每秒,有向东和径向向外的趋势。

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