Y. Chi, C. Shen, Junyan Liu, Zhihui Zhong, M. Owens, C. Scott, L. Barnard, Bingkun Yu, D. Heyner, H. Auster, I. Richter, Yuming Wang, Tielong Zhang, Jingnan Guo, B. Sánchez–Cano, Z. Pan, Zhuxuan Zou, Mengjiao Xu, L. Cheng, Z. Su, Dongwei Mao, Zhiyong Zhang, Can Wang, Zhiyong Wu, Guoqiang Wang, S. Xiao, Kai Liu, X. Hao, Yiren Li, Manming Chen, M. Lockwood
{"title":"BepiColombo、天文一号和MAVEN观测的多点行星际日冕物质抛射的动态演化","authors":"Y. Chi, C. Shen, Junyan Liu, Zhihui Zhong, M. Owens, C. Scott, L. Barnard, Bingkun Yu, D. Heyner, H. Auster, I. Richter, Yuming Wang, Tielong Zhang, Jingnan Guo, B. Sánchez–Cano, Z. Pan, Zhuxuan Zou, Mengjiao Xu, L. Cheng, Z. Su, Dongwei Mao, Zhiyong Zhang, Can Wang, Zhiyong Wu, Guoqiang Wang, S. Xiao, Kai Liu, X. Hao, Yiren Li, Manming Chen, M. Lockwood","doi":"10.3847/2041-8213/acd7e7","DOIUrl":null,"url":null,"abstract":"We present two multipoint interplanetary coronal mass ejections (ICMEs) detected by the Tianwen-1 and Mars Atmosphere and Volatile Evolution spacecraft at Mars and the BepiColombo (0.56 au ∼0.67 au) upstream of Mars from 2021 December 5 to 31. This is the first time that BepiColombo is used as an upstream solar wind monitor ahead of Mars and that Tianwen-1 is used to investigate the magnetic field characteristics of ICMEs at Mars. 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引用次数: 1
摘要
本文介绍了从2021年12月5日至31日在火星上游的BepiColombo (0.56 au ~ 0.67 au)和火星大气和挥发物演化探测器在火星和BepiColombo (0.56 au ~ 0.67 au)探测到的两个多点行星际日冕物质抛射(ICMEs)。这是BepiColombo卫星第一次被用作火星前的上游太阳风监测仪,也是天文一号卫星第一次被用来研究火星ICMEs的磁场特征。利用日球逆风外推时间模型将STEREO/SECCHI和SOHO/LASCO的日冕观测与多个原位观测相连接。12月4日爆发的第一次快速日冕物质抛射事件(~ 761.2 km s - 1)撞击了火星的中心,并从火星的西侧掠过了比皮可伦坡。周围缓慢的太阳风使ICME的西侧翼减速,表明ICME事件受到太阳风结构的显著扭曲。第二次缓慢的ICME事件(~ 390.7 km s−1)经历了从喷发到0.69 au距离内的加速,然后以周围太阳风的恒定速度行进。这些发现强调了背景太阳风在确定火星距离内ICMEs的行星际演化和全球形态方面的重要性。来自多个地点的观测对火星的空间天气研究是无价的,值得未来进行更多的探索。
The Dynamic Evolution of Multipoint Interplanetary Coronal Mass Ejections Observed with BepiColombo, Tianwen-1, and MAVEN
We present two multipoint interplanetary coronal mass ejections (ICMEs) detected by the Tianwen-1 and Mars Atmosphere and Volatile Evolution spacecraft at Mars and the BepiColombo (0.56 au ∼0.67 au) upstream of Mars from 2021 December 5 to 31. This is the first time that BepiColombo is used as an upstream solar wind monitor ahead of Mars and that Tianwen-1 is used to investigate the magnetic field characteristics of ICMEs at Mars. The Heliospheric Upwind Extrapolation time model was used to connect the multiple in situ observations and the coronagraph observations from STEREO/SECCHI and SOHO/LASCO. The first fast coronal mass ejection event (∼761.2 km s−1), which erupted on December 4, impacted Mars centrally and grazed BepiColombo by its western flank. The ambient slow solar wind decelerated the west flank of the ICME, implying that the ICME event was significantly distorted by the solar wind structure. The second slow ICME event (∼390.7 km s−1) underwent an acceleration from its eruption to a distance within 0.69 au and then traveled with the constant velocity of the ambient solar wind. These findings highlight the importance of background solar wind in determining the interplanetary evolution and global morphology of ICMEs up to Mars distance. Observations from multiple locations are invaluable for space weather studies at Mars and merit more exploration in the future.
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