Observations and modeling of magnetic flux tube refilling of the plasmasphere at geosynchronous orbit

The outer plasmasphere is eroded when the strength of the convection electric field increases. Following a return of lower levels of convection, the outer plasmasphere “refills” from the ionosphere. In situ observations of the cold (~1 eV) ion number density from geosynchronous orbit indicate that w...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics 2014-11, Vol.119 (11), p.9246-9255
Main Authors: Denton, M. H., Borovsky, J. E.
Format: Article
Language:English
Subjects:
Astrophysics
Atmosphere
Convection
Density
Estimates
geosynchronous orbit
Geosynchronous orbits
Ionosphere
Magnetic fields
Mathematical models
Neutral atmospheres
Orbits
Plasmasphere
Refilling
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Summary:The outer plasmasphere is eroded when the strength of the convection electric field increases. Following a return of lower levels of convection, the outer plasmasphere “refills” from the ionosphere. In situ observations of the cold (~1 eV) ion number density from geosynchronous orbit indicate that within ~48 h after plasmaspheric erosion events, the number density may return to a level of ~100 cm−3, consistent with previously reported values. Current theoretical estimates of refilling rates at geosynchronous orbit are inconsistent with such rapid refilling. In order to shed light on this issue, a theoretical investigation is carried out to determine the major factors governing the refilling process. While theoretical estimates of the refilling rate reported here still fall below the observed levels by at least a factor of 2, the results of this study indicate that the morphology of the neutral atmosphere, particularly the neutral atmosphere number density, is critical in controlling the rate of refilling at geosynchronous orbit. The strength of vertical E × B drifts and horizontal neutral winds is found to play only a minor role. Key Points Theoretical estimates of refilling are inconsistent with observationsNumber density observed ~100 cm−3 ~48 h after refilling commencesNeutral number density/composition key factors for the refilling rate at GEO
ISSN:2169-9380
2169-9402
DOI:10.1002/2014JA020491