与极光粒子降水有关的电离层等离子体结构

IF 3.4 2区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
F. Enengl, D. Kotova, Yaqi Jin, L. Clausen, W. Miloch
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引用次数: 5

摘要

极光粒子降水可能在电离层等离子体结构中发挥主要作用。使用闪烁接收器和斯瓦尔巴群岛朗伊尔城、尼奥松德和霍恩松德的全天空相机的多点测量,研究了极光粒子降水对等离子体结构的影响。这为我们研究极光的空间和时间动力学提供了独特的可能性。在这里,我们考虑了三个案例研究来研究等离子体结构如何与不同的极光形式相关。我们证明,影响GNSS信号的等离子体结构在极光形式的边缘最大。在这里,我们研究了两个稳定的弧,两个动态极光带和一个螺旋。特别是对于弧,我们发现极光极地边缘的相位闪烁指数升高。这是在电离层E区150公里处观测到的极光氧发射(557.7nm)。这一高度也被用作全球导航卫星系统信号的电离层穿透点,因为无论卫星高度和方位如何,观测结果都保持不变。此外,极光的时间演变(例如极光活动的开始和消退)与相位闪烁指数升高的观测之间可能存在时间延迟。这种时间延迟可以用粒子的强烈涌入来解释,这增加了等离子体密度,并导致重组进行得更长,这可能导致结构的持久性——一种“记忆效应”。即使在强烈的可见极光之后不久,也可以观察到高值的相位闪烁指数,并且在低强度的极光下可以保持显著。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ionospheric Plasma Structuring in Relation to Auroral Particle Precipitation
Auroral particle precipitation potentially plays a main role in ionospheric plasma structuring. The impact of auroral particle precipitation on plasma structuring is investigated using multi-point measurements from scintillation receivers and all sky cameras from Longyearbyen, Ny-Ålesund and Hornsund on Svalbard. This provides us with the unique possibility of studying the spatial and temporal dynamics of the aurora. Here we consider three case studies to investigate how plasma structuring is related to different auroral forms.     We demonstrate that plasma structuring impacting the GNSS signals is largest at the edges of auroral forms. Here we studied two stable arcs, two dynamic auroral bands and a spiral. Specifically for arcs we find elevated phase scintillation indices at the pole-ward edge of the aurora. This is observed for auroral oxygen emissions (557.7 nm) at 150~km in the ionospheric E-region. This altitude is also used as the ionospheric piercing point for the GNSS signals as the observations remain the same regardless of different satellite elevations and azimuths. Further, there may be a time delay between the temporal evolution of aurora (f.e. commencement and fading of auroral activity) and observations of elevated phase scintillation indices. The time delay could be explained by the intense influx of particles, which increases the plasma density and causes recombination to carry on longer, which may lead to a persistence of structures - a 'memory effect'. High values of phase scintillation indices can be observed even shortly after strong visible aurora and can then remain significant at low intensities of the aurora.
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来源期刊
Journal of Space Weather and Space Climate
Journal of Space Weather and Space Climate ASTRONOMY & ASTROPHYSICS-GEOCHEMISTRY & GEOPHYSICS
CiteScore
6.90
自引率
6.10%
发文量
40
审稿时长
8 weeks
期刊介绍: The Journal of Space Weather and Space Climate (SWSC) is an international multi-disciplinary and interdisciplinary peer-reviewed open access journal which publishes papers on all aspects of space weather and space climate from a broad range of scientific and technical fields including solar physics, space plasma physics, aeronomy, planetology, radio science, geophysics, biology, medicine, astronautics, aeronautics, electrical engineering, meteorology, climatology, mathematics, economy, informatics.
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