Formation and Eruption of a Hot Channel Magnetic Flux Rope in a Nested Double Null Magnetic System

Surui Yao, Yuandeng Shen, Chengrui Zhou, Dongxu Liu and Xinping Zhou
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Abstract

The coronal magnetic topology significantly affects the outcome of magnetic flux rope (MFR) eruptions. The recently reported nested double null magnetic system remains unclear as to how it affects MFR eruptions. Using observations from the New Vacuum Solar Telescope and the Solar Dynamics Observatory, we studied the formation and successful eruption of a hot channel MFR from NOAA active region AR 12173 on 2014 September 28. We observed that a hot channel MFR formed and erupted as a coronal mass ejection (CME), and the magnetic field of the source region was a nested double null magnetic system in which an inner magnetic null point system was nested by an outer fan–spine magnetic system. Observational analysis suggests that the origin of the MFR was due to magnetic reconnection at the inner null point, which was triggered by the photospheric swirling motions. The long-term shearing motion in the source region throughout around 26 hr might accumulate enough energy to power the eruption. Since previous studies showed that MFR eruptions from nested double null magnetic systems often result in weak jets and stalled or failed eruptions, it is hard to understand the generation of the large-scale CME in our case. A detailed comparison with previous studies reveals that the birth location of the MFR relative to the inner null point might be the critical physical factor for determining whether an MFR can erupt successfully or not in such a particular nested double null magnetic system.
嵌套双空磁性系统中热通道磁通量绳的形成和喷发
日冕磁拓扑结构对磁通量绳(MFR)爆发的结果有很大影响。最近报道的嵌套双空磁系如何影响磁通量绳喷发仍不清楚。利用新真空太阳望远镜和太阳动力学天文台的观测数据,我们研究了2014年9月28日NOAA活动区AR 12173的热通道MFR的形成和成功喷发。我们观测到热通道MFR以日冕物质抛射(CME)的形式形成并爆发,源区的磁场是一个嵌套的双空洞磁系,其中内层磁空洞点系与外层扇脊磁系嵌套。观测分析表明,MFR 的起源是由光球漩涡运动引发的内部空点的磁再连接。在大约26小时内,源区的长期剪切运动可能积累了足够的能量,为爆发提供了动力。由于之前的研究表明,嵌套双空磁系的MFR爆发通常会导致微弱的喷流和爆发停滞或失败,因此很难理解我们的案例中大尺度CME的产生。与以往研究的详细比较显示,相对于内空点的MFR诞生位置可能是决定MFR能否在这种特定嵌套双空磁系中成功爆发的关键物理因素。
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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