太阳活动在太阳周期 24 下降阶段对近地空间区域的影响

IF 2.6 2区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS
Zhaohai He, Jiyao Xu, Lei Dai, Suping Duan, Hong Gao, Guojun Wang, Ilan Roth, Chi Wang
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引用次数: 0

摘要

太阳周期包括近地空间区域的多尺度变化,包括等离子体、内辐射带(IRB)、电离层、中间层和低温层(MLT)。我们利用 TIMED 上 SABER 的中间层和热层位势高度和温度、中国子午工程的电离层 hmF2、IRB 的高能质子和 2013-2018 年区间内 Van Allen 探测器的等离子体电子密度,对太阳周期对这四个区域的影响程度进行了深入分析。通过分析这些量的变化,我们发现整个IRB、电离层和MLT区域在太阳最小时缩小,在太阳最大时伸展,尺度分别为103、50-102和1千米,而等离子体则呈现相反的趋势。这些量的傅立叶频谱是通过伦布-斯卡格尔周期图研究的。在 MLT 区域观测到了中期周期振荡(13.5 天、45 天和 52 天),与质点位置和地磁指数非常吻合,而在太阳 EUV 辐射和 IRB 中却没有观测到。这可能表明,这些振荡促进了磁暴和亚暴引起的 MLT 区域和质球之间的能量交换和质量运输。除了每年的变化之外,在 MLT 区域还没有观测到 IRB 中更高能量(102.6 MeV)的振荡周期。虽然高能质子可能会深入 MLT 区域,但对 MLT 区域的影响可能并不大。我们的研究结果揭示了某些数量与太阳周期多尺度调制之间的关系,这可能为近地空间区域的大规模运输提供帮助和监测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Solar Activity Effects on the Near-Earth Space Regions During the Descending Phase of Solar Cycle 24

The solar cycle includes multi-scale variations in the near-Earth space regions including plasmasphere, inner radiation belt (IRB), ionosphere, mesosphere and lower thermosphere (MLT). We present a thorough analysis of the extent of solar cycle effect on those four regions by using mesospheric and thermospheric geopotential height and temperature from SABER on TIMED, ionospheric hmF2 from Chinese Meridian Project, high-energy protons in IRB and electron density in plasmasphere from Van Allen Probes within 2013–2018 intervals. By analyzing evolutions of these quantities, we find that entire IRB, ionosphere and MLT region shrink at solar minimum and stretch at solar maximum by ∼103, 50–102, and 1 km scales, respectively, while plasmapause shows an opposite trend. Fourier spectra of these quantities have been investigated by Lomb–Scargle periodogram. The mid-term periodic oscillations (13.5-day, 45-day, and 52-day) have been observed in MLT region, matching well with plasmapause locations and geomagnetic indices, which have not been observed in solar EUV radiation and IRB. This may indicate that those oscillations facilitate energy exchange and mass transportation between MLT region and plasmasphere due to magnetic storms and substorms. The oscillation periods of higher energy (102.6 MeV) in IRB have not been observed in MLT region except for annual variations. The impact of higher energy protons on MLT regions may not be significant, although they could penetrate deeper into MLT region. Our results reveal relationships between some quantities and solar cycle multi-scale modulation, which may provide assistance and monitors for mass transportation in the near-Earth space regions.

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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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