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Solar wind—magnetosphere coupling during radial interplanetary magnetic field conditions: simultaneous multi-point observations

Solar wind—magnetosphere coupling during radial interplanetary magnetic field conditions: simultaneous multi-point observations
Solar wind—magnetosphere coupling during radial interplanetary magnetic field conditions: simultaneous multi-point observations

In-situ spacecraft missions are powerful assets to study processes that occur in space plasmas. One of their main limitations, however, is extrapolating such local measurements to the global scales of the system. To overcome this problem at least partially, multi-point measurements can be used. There are several multi-spacecraft missions currently operating in the Earth's magnetosphere, and the simultaneous use of the data collected by them provides new insights into the large-scale properties and evolution of magnetospheric plasma processes. In this work, we focus on studying the Earth's magnetopause (MP) using a conjunction between the Magnetospheric Multiscale and Cluster fleets, when both missions skimmed the MP for several hours at distant locations during radial interplanetary magnetic field (IMF) conditions. The observed MP positions as a function of the evolving solar wind conditions are compared to model predictions of the MP. We observe an inflation of the magnetosphere (∼0.7 RE), consistent with magnetosheath pressure decrease during radial IMF conditions, which is less pronounced on the flank ((Formula presented.) 0.2 RE). There is observational evidence of magnetic reconnection in the subsolar region for the whole encounter, and in the dusk flank for the last portion of the encounter, suggesting that reconnection was extending more than 15 RE. However, reconnection jets were not always observed, suggesting that reconnection was patchy, intermittent or both. Shear flows reduce the reconnection rate up to ∼30% in the dusk flank according to predictions, and the plasma β enhancement in the magnetosheath during radial IMF favors reconnection suppression by the diamagnetic drift.

magnetic reconnection, magnetopause (MP), magnetosphere, solar wind
2169-9380
Toledo-Redondo, S.
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Hwang, K.J.
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Escoubet, C.P.
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Lavraud, B.
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Fornieles, J.
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Aunai, N.
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Fear, R.C.
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Dargent, J.
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Fu, H.S.
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Fuselier, S.A.
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Genestreti, K.J.
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Khotyaintsev, Yu V.
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Li, W.Y.
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Norgren, C.
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Phan, T.D.
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Toledo-Redondo, S.
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Hwang, K.J.
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Escoubet, C.P.
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Lavraud, B.
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Fornieles, J.
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Aunai, N.
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Fear, R.C.
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Dargent, J.
6371849b-2c38-44bb-a6d4-81a19732b398
Fu, H.S.
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Fuselier, S.A.
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Genestreti, K.J.
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Khotyaintsev, Yu V.
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Li, W.Y.
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Norgren, C.
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Phan, T.D.
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Toledo-Redondo, S., Hwang, K.J., Escoubet, C.P., Lavraud, B., Fornieles, J., Aunai, N., Fear, R.C., Dargent, J., Fu, H.S., Fuselier, S.A., Genestreti, K.J., Khotyaintsev, Yu V., Li, W.Y., Norgren, C. and Phan, T.D. (2021) Solar wind—magnetosphere coupling during radial interplanetary magnetic field conditions: simultaneous multi-point observations. Journal of Geophysical Research: Space Physics, 126 (11), [e2021JA029506]. (doi:10.1029/2021JA029506).

Record type: Article

Abstract

In-situ spacecraft missions are powerful assets to study processes that occur in space plasmas. One of their main limitations, however, is extrapolating such local measurements to the global scales of the system. To overcome this problem at least partially, multi-point measurements can be used. There are several multi-spacecraft missions currently operating in the Earth's magnetosphere, and the simultaneous use of the data collected by them provides new insights into the large-scale properties and evolution of magnetospheric plasma processes. In this work, we focus on studying the Earth's magnetopause (MP) using a conjunction between the Magnetospheric Multiscale and Cluster fleets, when both missions skimmed the MP for several hours at distant locations during radial interplanetary magnetic field (IMF) conditions. The observed MP positions as a function of the evolving solar wind conditions are compared to model predictions of the MP. We observe an inflation of the magnetosphere (∼0.7 RE), consistent with magnetosheath pressure decrease during radial IMF conditions, which is less pronounced on the flank ((Formula presented.) 0.2 RE). There is observational evidence of magnetic reconnection in the subsolar region for the whole encounter, and in the dusk flank for the last portion of the encounter, suggesting that reconnection was extending more than 15 RE. However, reconnection jets were not always observed, suggesting that reconnection was patchy, intermittent or both. Shear flows reduce the reconnection rate up to ∼30% in the dusk flank according to predictions, and the plasma β enhancement in the magnetosheath during radial IMF favors reconnection suppression by the diamagnetic drift.

Text
JGR Space Physics - 2021 - Toledo‐Redondo  - Solar Wind Magnetosphere Coupling During Radial Interplanetary Magnetic Field - Version of Record
Available under License Creative Commons Attribution.
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Accepted/In Press date: 26 October 2021
e-pub ahead of print date: 7 November 2021
Published date: 18 November 2021
Keywords: magnetic reconnection, magnetopause (MP), magnetosphere, solar wind
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Identifiers

Local EPrints ID: 491568
URI: http://eprints.soton.ac.uk/id/eprint/491568
DOI: doi:10.1029/2021JA029506
ISSN: 2169-9380
PURE UUID: fa5f6707-287d-4a0b-bed2-8a9312669049
ORCID for R.C. Fear: ORCID iD orcid.org/0000-0003-0589-7147

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Date deposited: 26 Jun 2024 16:33
Last modified: 27 Jun 2024 01:45

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Contributors

Author: S. Toledo-Redondo
Author: K.J. Hwang
Author: C.P. Escoubet
Author: B. Lavraud
Author: J. Fornieles
Author: N. Aunai
Author: R.C. Fear ORCID iD
Author: J. Dargent
Author: H.S. Fu
Author: S.A. Fuselier
Author: K.J. Genestreti
Author: Yu V. Khotyaintsev
Author: W.Y. Li
Author: C. Norgren
Author: T.D. Phan

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