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Main Authors: Ma, Mengxuan, Yang, Liping, Shen, Fang, Shen, Chenglong, Chi, Yutian, Wang, Yuming, Zhou, Yufen, Zhang, Man, Heyner, Daniel, Auster, Uli, Richter, Ingo, Sanchez-Cano, Beatriz
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.20803
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author Ma, Mengxuan
Yang, Liping
Shen, Fang
Shen, Chenglong
Chi, Yutian
Wang, Yuming
Zhou, Yufen
Zhang, Man
Heyner, Daniel
Auster, Uli
Richter, Ingo
Sanchez-Cano, Beatriz
author_facet Ma, Mengxuan
Yang, Liping
Shen, Fang
Shen, Chenglong
Chi, Yutian
Wang, Yuming
Zhou, Yufen
Zhang, Man
Heyner, Daniel
Auster, Uli
Richter, Ingo
Sanchez-Cano, Beatriz
contents The magnetic orientation of coronal mass ejections (CMEs) is of great importance to understand their space weather effects. Although many evidences suggest that CMEs can undergo significant rotation during the early phases of evolution in the solar corona, there are few reports that CMEs rotate in the interplanetary space. In this work, we use multi-spacecraft observations and a numerical simulation starting from the lower corona close to the solar surface to understand the CME event on 2021 December 4, with an emphatic investigation of its rotation. This event is observed as a partial halo CME from the back side of the Sun by coronagraphs, and reaches the BepiColombo spacecraft and the MAVEN/Tianwen-1 as a magnetic flux rope-like structure. The simulation discloses that in the solar corona the CME is approximately a translational motion, while the interplanetary propagation process evidences a gradual change of axis orientation of the CME's flux rope-like structure. It is also found that the downside and the right flank of the CME moves with the fast solar wind, and the upside does in the slow-speed stream. The different parts of the CME with different speeds generate the nonidentical displacements of its magnetic structure, resulting in the rotation of the CME in the interplanetary space. Furthermore, at the right flank of the CME exists a corotating interaction region (CIR), which makes the orientation of the CME alter, and also deviates from its route due to the CME. These results provide new insight on interpreting CMEs' dynamics and structures during their travelling through the heliosphere.
format Preprint
id arxiv_https___arxiv_org_abs_2410_20803
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Interplanetary Rotation of 2021 December 4 CME
Ma, Mengxuan
Yang, Liping
Shen, Fang
Shen, Chenglong
Chi, Yutian
Wang, Yuming
Zhou, Yufen
Zhang, Man
Heyner, Daniel
Auster, Uli
Richter, Ingo
Sanchez-Cano, Beatriz
Solar and Stellar Astrophysics
Space Physics
The magnetic orientation of coronal mass ejections (CMEs) is of great importance to understand their space weather effects. Although many evidences suggest that CMEs can undergo significant rotation during the early phases of evolution in the solar corona, there are few reports that CMEs rotate in the interplanetary space. In this work, we use multi-spacecraft observations and a numerical simulation starting from the lower corona close to the solar surface to understand the CME event on 2021 December 4, with an emphatic investigation of its rotation. This event is observed as a partial halo CME from the back side of the Sun by coronagraphs, and reaches the BepiColombo spacecraft and the MAVEN/Tianwen-1 as a magnetic flux rope-like structure. The simulation discloses that in the solar corona the CME is approximately a translational motion, while the interplanetary propagation process evidences a gradual change of axis orientation of the CME's flux rope-like structure. It is also found that the downside and the right flank of the CME moves with the fast solar wind, and the upside does in the slow-speed stream. The different parts of the CME with different speeds generate the nonidentical displacements of its magnetic structure, resulting in the rotation of the CME in the interplanetary space. Furthermore, at the right flank of the CME exists a corotating interaction region (CIR), which makes the orientation of the CME alter, and also deviates from its route due to the CME. These results provide new insight on interpreting CMEs' dynamics and structures during their travelling through the heliosphere.
title Interplanetary Rotation of 2021 December 4 CME
topic Solar and Stellar Astrophysics
Space Physics
url https://arxiv.org/abs/2410.20803