Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation

Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation

<p>Fast plasma flows produced as outflow jets from reconnection sites or X lines are a key feature of the dynamics in the Earth's magnetosphere. We have used a polar plane simulation of the hybrid-Vlasov model Vlasiator, driven by steady southward interplanetary magnetic field and fast...

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Main Authors: L. Juusola, S. Hoilijoki, Y. Pfau-Kempf, U. Ganse, R. Jarvinen, M. Battarbee, E. Kilpua, L. Turc, M. Palmroth
Format: Article
Language:English
Published: Copernicus Publications 2018-09-01
Series:Annales Geophysicae
Online Access:https://www.ann-geophys.net/36/1183/2018/angeo-36-1183-2018.pdf
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spelling doaj-5dc4597f5dcd4915b6ba6feaa643ee202020-11-24T23:26:28ZengCopernicus PublicationsAnnales Geophysicae0992-76891432-05762018-09-01361183119910.5194/angeo-36-1183-2018Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulationL. Juusola0L. Juusola1S. Hoilijoki2S. Hoilijoki3Y. Pfau-Kempf4U. Ganse5R. Jarvinen6R. Jarvinen7M. Battarbee8E. Kilpua9L. Turc10M. Palmroth11M. Palmroth12Finnish Meteorological Institute, Helsinki, FinlandDepartment of Physics, University of Helsinki, Helsinki, FinlandDepartment of Physics, University of Helsinki, Helsinki, FinlandLaboratory for Atmospheric and Space Physics, University of Colorado Boulder, Boulder, Colorado, USADepartment of Physics, University of Helsinki, Helsinki, FinlandDepartment of Physics, University of Helsinki, Helsinki, FinlandFinnish Meteorological Institute, Helsinki, FinlandDepartment of Electronics and Nanoengineering, School of Electrical Engineering, Aalto University, Espoo, FinlandDepartment of Physics, University of Helsinki, Helsinki, FinlandDepartment of Physics, University of Helsinki, Helsinki, FinlandDepartment of Physics, University of Helsinki, Helsinki, FinlandFinnish Meteorological Institute, Helsinki, FinlandDepartment of Physics, University of Helsinki, Helsinki, Finland<p>Fast plasma flows produced as outflow jets from reconnection sites or X lines are a key feature of the dynamics in the Earth's magnetosphere. We have used a polar plane simulation of the hybrid-Vlasov model Vlasiator, driven by steady southward interplanetary magnetic field and fast solar wind, to study fast plasma sheet ion flows and related magnetic field structures in the Earth's magnetotail. In the simulation, lobe reconnection starts to produce fast flows after the increasing pressure in the lobes has caused the plasma sheet to thin sufficiently. The characteristics of the earthward and tailward fast flows and embedded magnetic field structures produced by multi-point tail reconnection are in general agreement with spacecraft measurements reported in the literature. The structuring of the flows is caused by internal processes: interactions between major X points determine the earthward or tailward direction of the flow, while interactions between minor X points, associated with leading edges of magnetic islands carried by the flow, induce local minima and maxima in the flow speed. Earthward moving flows are stopped and diverted duskward in an oscillatory (bouncing) manner at the transition region between tail-like and dipolar magnetic fields. Increasing and decreasing dynamic pressure of the flows causes the transition region to shift earthward and tailward, respectively. The leading edge of the train of earthward flow bursts is associated with an earthward propagating dipolarization front, while the leading edge of the train of tailward flow bursts is associated with a tailward propagating plasmoid. The impact of the dipolarization front with the dipole field causes magnetic field variations in the Pi2 range. Major X points can move either earthward or tailward, although tailward motion is more common. They are generally not advected by the ambient flow. Instead, their velocity is better described by local parameters, such that an X point moves in the direction of increasing reconnection electric field strength. Our results indicate that ion kinetics might be sufficient to describe the behavior of plasma sheet bulk ion flows produced by tail reconnection in global near-Earth simulations.</p>https://www.ann-geophys.net/36/1183/2018/angeo-36-1183-2018.pdf
collection DOAJ
language English
format Article
sources DOAJ
author L. Juusola
L. Juusola
S. Hoilijoki
S. Hoilijoki
Y. Pfau-Kempf
U. Ganse
R. Jarvinen
R. Jarvinen
M. Battarbee
E. Kilpua
L. Turc
M. Palmroth
M. Palmroth
spellingShingle L. Juusola
L. Juusola
S. Hoilijoki
S. Hoilijoki
Y. Pfau-Kempf
U. Ganse
R. Jarvinen
R. Jarvinen
M. Battarbee
E. Kilpua
L. Turc
M. Palmroth
M. Palmroth
Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation
Annales Geophysicae
author_facet L. Juusola
L. Juusola
S. Hoilijoki
S. Hoilijoki
Y. Pfau-Kempf
U. Ganse
R. Jarvinen
R. Jarvinen
M. Battarbee
E. Kilpua
L. Turc
M. Palmroth
M. Palmroth
author_sort L. Juusola
title Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation
title_short Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation
title_full Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation
title_fullStr Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation
title_full_unstemmed Fast plasma sheet flows and X line motion in the Earth's magnetotail: results from a global hybrid-Vlasov simulation
title_sort fast plasma sheet flows and x line motion in the earth's magnetotail: results from a global hybrid-vlasov simulation
publisher Copernicus Publications
series Annales Geophysicae
issn 0992-7689
1432-0576
publishDate 2018-09-01
description <p>Fast plasma flows produced as outflow jets from reconnection sites or X lines are a key feature of the dynamics in the Earth's magnetosphere. We have used a polar plane simulation of the hybrid-Vlasov model Vlasiator, driven by steady southward interplanetary magnetic field and fast solar wind, to study fast plasma sheet ion flows and related magnetic field structures in the Earth's magnetotail. In the simulation, lobe reconnection starts to produce fast flows after the increasing pressure in the lobes has caused the plasma sheet to thin sufficiently. The characteristics of the earthward and tailward fast flows and embedded magnetic field structures produced by multi-point tail reconnection are in general agreement with spacecraft measurements reported in the literature. The structuring of the flows is caused by internal processes: interactions between major X points determine the earthward or tailward direction of the flow, while interactions between minor X points, associated with leading edges of magnetic islands carried by the flow, induce local minima and maxima in the flow speed. Earthward moving flows are stopped and diverted duskward in an oscillatory (bouncing) manner at the transition region between tail-like and dipolar magnetic fields. Increasing and decreasing dynamic pressure of the flows causes the transition region to shift earthward and tailward, respectively. The leading edge of the train of earthward flow bursts is associated with an earthward propagating dipolarization front, while the leading edge of the train of tailward flow bursts is associated with a tailward propagating plasmoid. The impact of the dipolarization front with the dipole field causes magnetic field variations in the Pi2 range. Major X points can move either earthward or tailward, although tailward motion is more common. They are generally not advected by the ambient flow. Instead, their velocity is better described by local parameters, such that an X point moves in the direction of increasing reconnection electric field strength. Our results indicate that ion kinetics might be sufficient to describe the behavior of plasma sheet bulk ion flows produced by tail reconnection in global near-Earth simulations.</p>
url https://www.ann-geophys.net/36/1183/2018/angeo-36-1183-2018.pdf
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