A Pileup of Coronal Mass Ejections Produced the Largest Geomagnetic Storm in Two Decades

arXiv - PHYS - Space Physics Pub Date : 2024-09-17 DOI:arxiv-2409.11492

Ying D. Liu, Huidong Hu, Xiaowei Zhao, Chong Chen, Rui Wang

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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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日冕物质抛射堆积引发二十年来最大的地磁风暴

2024年5月发生了二十年来最大的地磁暴，其最大值$D_{\rm st}$为$-412$ nT。我们结合多点成像和现场观测，研究了它的太阳和行星际起源。源活动区 NOAA AR 13664 表现出了非同寻常的活动，并产生了连续的晕喷发，这是在地球上观测到的两个复杂喷出物的原因。我们获得了有关太阳超级风暴的形成以及日冕物质抛射的中尺度变化如何影响地球效应的重要发现：（1）2024 年 5 月的风暴支持了太阳超级风暴在本质上是 "完美风暴 "的假设，即："完美风暴 "是由各种条件的组合造成的、(2)造成地磁超级风暴的第一个复合抛射物显示地球和 STEREO A 之间的磁场和相关 "地球效应 "存在相当大的差异，尽管存在中尺度的分隔；(3)在地球的地球效应方面发现了两种截然不同的复合抛射物情况，这在很大程度上是由于同一活动区域内不同的磁场配置造成的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Space Physics

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