Comparison between vortices created and evolving during fixed and dynamic solar wind conditions
We employ Magnetohydrodynamic (MHD) simulations to examine the creation and evolution of plasma vortices within the Earth's magnetosphere for steady solar wind plasma conditions. Very few vortices form during intervals of such solar wind conditions. Those that do remain in fixed positions fo...
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Copernicus Publications
2013-08-01
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| Series: | Annales Geophysicae |
| Online Access: | https://www.ann-geophys.net/31/1463/2013/angeo-31-1463-2013.pdf |
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doaj-bca2fce7f956496db71b49e8824f5b282020-11-24T23:18:57ZengCopernicus PublicationsAnnales Geophysicae0992-76891432-05762013-08-01311463148310.5194/angeo-31-1463-2013Comparison between vortices created and evolving during fixed and dynamic solar wind conditionsY. M. Collado-Vega0R. L. Kessel1D. G. Sibeck2V. L. Kalb3R. A. Boller4L. Rastaetter5NASA Goddard Space Flight Center, Space Weather Laboratory, Code 674, Greenbelt, MD, USANASA Headquarters, SMD, Heliophysics Division, Washington, D.C., USANASA Goddard Space Flight Center, Space Weather Laboratory, Code 674, Greenbelt, MD, USANASA Goddard Space Flight Center, Terrestrial Information Systems Laboratory, Code 619, Greenbelt, MD, USANASA Goddard Space Flight Center, Science Data Systems Branch, Code 586, Greenbelt, MD, USANASA Goddard Space Flight Center, Space Weather Laboratory, Code 674, Greenbelt, MD, USAWe employ Magnetohydrodynamic (MHD) simulations to examine the creation and evolution of plasma vortices within the Earth's magnetosphere for steady solar wind plasma conditions. Very few vortices form during intervals of such solar wind conditions. Those that do remain in fixed positions for long periods (often hours) and exhibit rotation axes that point primarily in the <i>x</i> or <i>y</i> direction, parallel (or antiparallel) to the local magnetospheric magnetic field direction. Occasionally, the orientation of the axes rotates from the <i>x</i> direction to another direction. We compare our results with simulations previously done for unsteady solar wind conditions. By contrast, these vortices that form during intervals of varying solar wind conditions exhibit durations ranging from seconds (in the case of those with axes in the <i>x</i> or <i>y</i> direction) to minutes (in the case of those with axes in the <i>z</i> direction) and convect antisunward. The local-time dependent sense of rotation seen in these previously reported vortices suggests an interpretation in terms of the Kelvin–Helmholtz instability. For steady conditions, the biggest vortices developed on the dayside (about 6 <i>R</i><sub>E</sub> in diameter), had their rotation axes aligned with the <i>y</i> direction and had the longest periods of duration. We attribute these vortices to the flows set up by reconnection on the high-latitude magnetopause during intervals of northward Interplanetary Magnetic Field (IMF) orientation. This is the first time that vortices due to high-latitude reconnection have been visualized. The model also successfully predicts the principal characteristics of previously reported plasma vortices within the magnetosphere, namely their dimension, flow velocities, and durations.https://www.ann-geophys.net/31/1463/2013/angeo-31-1463-2013.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Y. M. Collado-Vega R. L. Kessel D. G. Sibeck V. L. Kalb R. A. Boller L. Rastaetter |
| spellingShingle |
Y. M. Collado-Vega R. L. Kessel D. G. Sibeck V. L. Kalb R. A. Boller L. Rastaetter Comparison between vortices created and evolving during fixed and dynamic solar wind conditions Annales Geophysicae |
| author_facet |
Y. M. Collado-Vega R. L. Kessel D. G. Sibeck V. L. Kalb R. A. Boller L. Rastaetter |
| author_sort |
Y. M. Collado-Vega |
| title |
Comparison between vortices created and evolving during fixed and dynamic solar wind conditions |
| title_short |
Comparison between vortices created and evolving during fixed and dynamic solar wind conditions |
| title_full |
Comparison between vortices created and evolving during fixed and dynamic solar wind conditions |
| title_fullStr |
Comparison between vortices created and evolving during fixed and dynamic solar wind conditions |
| title_full_unstemmed |
Comparison between vortices created and evolving during fixed and dynamic solar wind conditions |
| title_sort |
comparison between vortices created and evolving during fixed and dynamic solar wind conditions |
| publisher |
Copernicus Publications |
| series |
Annales Geophysicae |
| issn |
0992-7689 1432-0576 |
| publishDate |
2013-08-01 |
| description |
We employ Magnetohydrodynamic (MHD) simulations to examine the creation and evolution of
plasma vortices within the Earth's magnetosphere for steady solar wind plasma
conditions. Very few vortices form during intervals of such solar wind
conditions. Those that do remain in fixed positions for long periods
(often hours) and exhibit rotation axes that point primarily in the <i>x</i> or
<i>y</i>
direction, parallel (or antiparallel) to the local magnetospheric magnetic
field direction. Occasionally, the orientation of the axes rotates from the
<i>x</i> direction to another direction. We compare our results with simulations
previously done for unsteady solar wind conditions. By contrast, these
vortices that form during intervals of varying solar wind conditions exhibit
durations ranging from seconds (in the case of those with axes in the <i>x</i> or
<i>y</i>
direction) to minutes (in the case of those with axes in the <i>z</i> direction) and
convect antisunward. The local-time dependent sense of rotation seen in
these previously reported vortices suggests an interpretation in terms of the
Kelvin–Helmholtz instability. For steady conditions, the biggest vortices
developed on the dayside (about 6 <i>R</i><sub>E</sub> in diameter), had their
rotation axes aligned with the <i>y</i> direction and had the longest periods of
duration. We attribute these vortices to the flows set up by reconnection on
the high-latitude magnetopause during intervals of northward Interplanetary Magnetic Field (IMF) orientation.
This is the first time that vortices due to high-latitude reconnection have
been visualized. The model also successfully predicts the principal
characteristics of previously reported plasma vortices within the
magnetosphere, namely their dimension, flow velocities, and durations. |
| url |
https://www.ann-geophys.net/31/1463/2013/angeo-31-1463-2013.pdf |
| work_keys_str_mv |
AT ymcolladovega comparisonbetweenvorticescreatedandevolvingduringfixedanddynamicsolarwindconditions AT rlkessel comparisonbetweenvorticescreatedandevolvingduringfixedanddynamicsolarwindconditions AT dgsibeck comparisonbetweenvorticescreatedandevolvingduringfixedanddynamicsolarwindconditions AT vlkalb comparisonbetweenvorticescreatedandevolvingduringfixedanddynamicsolarwindconditions AT raboller comparisonbetweenvorticescreatedandevolvingduringfixedanddynamicsolarwindconditions AT lrastaetter comparisonbetweenvorticescreatedandevolvingduringfixedanddynamicsolarwindconditions |
| _version_ |
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