The Colocation of Magnetic Reconnection and Current Disruption in Jovian Middle Magnetosphere

Dong Xiao Pan; Zhong Hua Yao; Rui Long Guo; Christopher S. Arridge; Licia C. Ray; Yong Zhao; George Clark; I. Jonathan Rae; Anthony T.Y. Lui; Bin Zheng Zhang; Yong Wei; Xu Zhi Zhou; Hui Shan Fu; John E.P. Connerney; Scott J. Bolton

doi:10.3847/2041-8213/ad5962

The Colocation of Magnetic Reconnection and Current Disruption in Jovian Middle Magnetosphere

Dong Xiao Pan
, Zhong Hua Yao
, Rui Long Guo
, Christopher S. Arridge
, Licia C. Ray
, Yong Zhao
, George Clark
, I. Jonathan Rae
, Anthony T.Y. Lui
, Bin Zheng Zhang
, Yong Wei
, Xu Zhi Zhou
, Hui Shan Fu
, John E.P. Connerney
, Scott J. Bolton

空间与地球科学学院

China University of Geosciences, Beijing
The University of Hong Kong
CAS - Institute of Geology and Geophysics
Shandong University
Lancaster University
Johns Hopkins University Applied Physics Laboratory
Northumbria University
Peking University
Space Research Corporation
NASA Goddard Space Flight Center
Southwest Research Institute

科研成果: 期刊稿件 › 文章 › 同行评审

2 引用（Scopus）

摘要

Magnetic reconnection and current disruption are two key processes in driving energy conversion and dissipation in planetary magnetospheres. At the Earth, the two processes usually occur at different locations: the current disruption process occurs more frequently in the near-Earth magnetotail ∼10 R _E, while the magnetotail reconnection process is expected to take place in the more distant region where the current sheet is thinner. Occasionally, under very intense solar wind perturbations, reconnection could be located closer to the Earth where current disruption processes usually operate. But it is unclear what the situation is at giant planets, in which the plasma environment is very different from the Earth. In this study, we investigate a middle-Jupiter reconnection event at ∼43 R _J. During the event, the inferred integrated cross-field currents were substantially reduced, which we argue is a signature of current disruption. In this case, we suggest that magnetic reconnection could be colocated with a current disruption process in the Jovian magnetosphere, which is roughly analogous to the situation in the extremely perturbed Earth’s magnetosphere.

源语言	英语
文章编号	L35
期刊	Astrophysical Journal Letters
卷	969
期	2
DOI	https://doi.org/10.3847/2041-8213/ad5962
出版状态	已出版 - 1 7月 2024

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Pan, D. X., Yao, Z. H., Guo, R. L., Arridge, C. S., Ray, L. C., Zhao, Y., Clark, G., Rae, I. J., Lui, A. T. Y., Zhang, B. Z., Wei, Y., Zhou, X. Z., Fu, H. S., Connerney, J. E. P., & Bolton, S. J. (2024). The Colocation of Magnetic Reconnection and Current Disruption in Jovian Middle Magnetosphere. Astrophysical Journal Letters, 969(2), 文章 L35. https://doi.org/10.3847/2041-8213/ad5962

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title = "The Colocation of Magnetic Reconnection and Current Disruption in Jovian Middle Magnetosphere",

abstract = "Magnetic reconnection and current disruption are two key processes in driving energy conversion and dissipation in planetary magnetospheres. At the Earth, the two processes usually occur at different locations: the current disruption process occurs more frequently in the near-Earth magnetotail ∼10 R E, while the magnetotail reconnection process is expected to take place in the more distant region where the current sheet is thinner. Occasionally, under very intense solar wind perturbations, reconnection could be located closer to the Earth where current disruption processes usually operate. But it is unclear what the situation is at giant planets, in which the plasma environment is very different from the Earth. In this study, we investigate a middle-Jupiter reconnection event at ∼43 R J. During the event, the inferred integrated cross-field currents were substantially reduced, which we argue is a signature of current disruption. In this case, we suggest that magnetic reconnection could be colocated with a current disruption process in the Jovian magnetosphere, which is roughly analogous to the situation in the extremely perturbed Earth{\textquoteright}s magnetosphere.",

author = "Pan, \{Dong Xiao\} and Yao, \{Zhong Hua\} and Guo, \{Rui Long\} and Arridge, \{Christopher S.\} and Ray, \{Licia C.\} and Yong Zhao and George Clark and Rae, \{I. Jonathan\} and Lui, \{Anthony T.Y.\} and Zhang, \{Bin Zheng\} and Yong Wei and Zhou, \{Xu Zhi\} and Fu, \{Hui Shan\} and Connerney, \{John E.P.\} and Bolton, \{Scott J.\}",

note = "Publisher Copyright: {\textcopyright} 2024. The Author(s). Published by the American Astronomical Society.",

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doi = "10.3847/2041-8213/ad5962",

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T1 - The Colocation of Magnetic Reconnection and Current Disruption in Jovian Middle Magnetosphere

AU - Pan, Dong Xiao

AU - Yao, Zhong Hua

AU - Guo, Rui Long

AU - Arridge, Christopher S.

AU - Ray, Licia C.

AU - Zhao, Yong

AU - Clark, George

AU - Rae, I. Jonathan

AU - Lui, Anthony T.Y.

AU - Zhang, Bin Zheng

AU - Wei, Yong

AU - Zhou, Xu Zhi

AU - Fu, Hui Shan

AU - Connerney, John E.P.

AU - Bolton, Scott J.

PY - 2024/7/1

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N2 - Magnetic reconnection and current disruption are two key processes in driving energy conversion and dissipation in planetary magnetospheres. At the Earth, the two processes usually occur at different locations: the current disruption process occurs more frequently in the near-Earth magnetotail ∼10 R E, while the magnetotail reconnection process is expected to take place in the more distant region where the current sheet is thinner. Occasionally, under very intense solar wind perturbations, reconnection could be located closer to the Earth where current disruption processes usually operate. But it is unclear what the situation is at giant planets, in which the plasma environment is very different from the Earth. In this study, we investigate a middle-Jupiter reconnection event at ∼43 R J. During the event, the inferred integrated cross-field currents were substantially reduced, which we argue is a signature of current disruption. In this case, we suggest that magnetic reconnection could be colocated with a current disruption process in the Jovian magnetosphere, which is roughly analogous to the situation in the extremely perturbed Earth’s magnetosphere.

AB - Magnetic reconnection and current disruption are two key processes in driving energy conversion and dissipation in planetary magnetospheres. At the Earth, the two processes usually occur at different locations: the current disruption process occurs more frequently in the near-Earth magnetotail ∼10 R E, while the magnetotail reconnection process is expected to take place in the more distant region where the current sheet is thinner. Occasionally, under very intense solar wind perturbations, reconnection could be located closer to the Earth where current disruption processes usually operate. But it is unclear what the situation is at giant planets, in which the plasma environment is very different from the Earth. In this study, we investigate a middle-Jupiter reconnection event at ∼43 R J. During the event, the inferred integrated cross-field currents were substantially reduced, which we argue is a signature of current disruption. In this case, we suggest that magnetic reconnection could be colocated with a current disruption process in the Jovian magnetosphere, which is roughly analogous to the situation in the extremely perturbed Earth’s magnetosphere.

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DO - 10.3847/2041-8213/ad5962

M3 - 文章

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VL - 969

JO - Astrophysical Journal Letters

JF - Astrophysical Journal Letters

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The Colocation of Magnetic Reconnection and Current Disruption in Jovian Middle Magnetosphere

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