Ying D. Liu, Huidong Hu, Xiaowei Zhao, Chong Chen, Rui Wang
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引用次数: 0
Abstract
The largest geomagnetic storm in two decades occurred in 2024 May with a
minimum $D_{\rm st}$ of $-412$ nT. We examine its solar and interplanetary
origins by combining multipoint imaging and in situ observations. The source
active region, NOAA AR 13664, exhibited extraordinary activity and produced
successive halo eruptions, which were responsible for two complex ejecta
observed at the Earth. In situ measurements from STEREO A, which was
$12.6^{\circ}$ apart, allow us to compare the ``geo-effectiveness" at the Earth
and STEREO A. We obtain key findings concerning the formation of solar
superstorms and how mesoscale variations of coronal mass ejections affect
geo-effectiveness: (1) the 2024 May storm supports the hypothesis that solar
superstorms are ``perfect storms" in nature, i.e., a combination of
circumstances resulting in an event of an unusual magnitude; (2) the first
complex ejecta, which caused the geomagnetic superstorm, shows considerable
differences in the magnetic field and associated ``geo-effectiveness" between
the Earth and STEREO A, despite a mesoscale separation; and (3) two contrasting
cases of complex ejecta are found in terms of the geo-effectiveness at the
Earth, which is largely due to different magnetic field configurations within
the same active region.
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