Effects of Storm‐Time Winds on Ionospheric Pre‐Midnight Equatorial Plasma Bubbles Over South America as Observed by ICON and GOLD

This study uses satellite measurements of plasma densities and thermospheric winds to analyze the effects of the November 2021 geomagnetic storm on ionospheric pre‐midnight topside plasma bubbles over South America. Using observations from the Ionospheric Connection Explorer (ICON) and the Global‐sc...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics 2024-10, Vol.129 (10), p.n/a
Main Authors: González, Gilda, Wu, Yen‐Jung, Gasque, L. Claire, Triplett, Colin C., Harding, Brian J., Immel, Thomas J.
Format: Article
Language:English
Subjects:
Auroral electrojet
Auroral electrojets
Bubbles
Communication
Electric fields
Electrojets
equatorial plasma bubbles
Equatorial regions
Geomagnetic storm effects
Geomagnetic storms
Geomagnetism
GOLD
ICON
Interplanetary magnetic field
Ionosphere
Ionospheric irregularities
Irregularities
Magnetic fields
Magnetic storms
Meridional wind
Navigation systems
Performance degradation
Performance prediction
Plasma
Plasma bubbles
Prediction models
Recovery
SAMA
Satellite observation
Satellites
Storm effects
Storms
Thermosphere
Thermospheric winds
Time measurement
Wind
Wind effects
Zonal winds
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Summary:This study uses satellite measurements of plasma densities and thermospheric winds to analyze the effects of the November 2021 geomagnetic storm on ionospheric pre‐midnight topside plasma bubbles over South America. Using observations from the Ionospheric Connection Explorer (ICON) and the Global‐scale Observations of the Limb and Disk (GOLD) satellites, we find that pre‐midnight topside plasma bubbles were inhibited over eastern South America during the recovery phase of the storm. This is particularly notable because of the otherwise high occurrence rate of plasma bubbles at these longitudes during this season. This inhibition coincided with the recovery phase of the geomagnetic storm, marked by a northward turning of the z‐component of the interplanetary magnetic field (IMFBz) and quiet‐time values of the SuperMAG Auroral Electrojet Index (SME). We observed a westward turning of the zonal wind before the bubble inhibition, so we conclude the inhibition of topside plasma bubbles is likely related to a westward disturbance dynamo electric field (DDEF) causing a downward E×B $\mathbf{E}\times \mathbf{B}$ drift and suppress the growth of the instability responsible for bubble development. Contrary to theoretical predictions, we do not observe notable changes to the meridional wind during the event. These results provide new insights into the ionosphere‐thermosphere system's response to geomagnetic storms and highlight the role of wind patterns in inhibiting ionospheric irregularities, contributing to better predictive models for these phenomena. Plain Language Summary Geomagnetic storms negatively affect communication and navigation systems by producing unpredictable changes in ionospheric densities. Plasma bubbles are irregularities in the ionosphere that occur mainly in the equatorial region and may be affected by geomagnetic storms. Studying plasma bubbles is crucial because they can significantly reduce the performance of communication and navigation systems, leading to signal loss or degradation. We conducted a study on how a geomagnetic storm in November 2021 affected the occurrence of pre‐midnight plasma bubbles over South America. Using data from two satellites (ICON and GOLD), we observed that these plasma bubbles disappeared during the storm's recovery phase. Our analysis suggests that this inhibition is likely linked to changes in wind patterns in the ionosphere. Specifically, a westward wind created conditions that prevented the generation of pl
ISSN:2169-9380
2169-9402
DOI:10.1029/2024JA033111