Ionospheric Disturbances and Irregularities During the 25–26 August 2018 Geomagnetic Storm

Ionospheric Disturbances and Irregularities During the 25–26 August 2018 Geomagnetic Storm

We use ground‐based (GNSS, SuperDARN, and ionosondes) and space‐borne (Swarm, CSES, and DMSP) instruments to study ionospheric disturbances due to the 25–26 August 2018 geomagnetic storm. The strongest large‐scale storm‐time enhancements were detected over the Asian and Pacific regions during the ma...

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Veröffentlicht in:Journal of geophysical research. Space physics 2022-01, Vol.127 (1), p.n/a
Hauptverfasser: Astafyeva, E., Yasyukevich, Y. V., Maletckii, B., Oinats, A., Vesnin, A., Yasyukevich, A. S., Syrovatskii, S., Guendouz, N.
Format: Artikel
Sprache:eng
Schlagworte:
Auroral oval
Auroral zone
Auroral zones
Equatorial ionization anomaly
Geomagnetic storms
Geomagnetism
Hemispheres
Ionization
Ionosondes
ionosphere
Ionospheric disturbances
ionospheric irregularities
Ionospheric trough
Irregularities
Latitude
Magnetic storms
multi‐instrumental approach
Particle precipitation
Plasma bubbles
Precipitation
ROTI
Sciences of the Universe
Storms
Total Electron Content
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Zusammenfassung:We use ground‐based (GNSS, SuperDARN, and ionosondes) and space‐borne (Swarm, CSES, and DMSP) instruments to study ionospheric disturbances due to the 25–26 August 2018 geomagnetic storm. The strongest large‐scale storm‐time enhancements were detected over the Asian and Pacific regions during the main and early recovery phases of the storm. In the American sector, there occurred the most complex effects caused by the action of multiple drivers. At the beginning of the storm, a large positive disturbance occurred over North America at low and high latitudes, driven by the storm‐time reinforcement of the equatorial ionization anomaly (at low latitudes) and by particle precipitation (at high latitudes). During local nighttime hours, we observed numerous medium‐scale positive and negative ionospheric disturbances at middle and high latitudes that were attributed to a storm‐enhanced density (SED)‐plume, mid‐latitude ionospheric trough, and particle precipitation in the auroral zone. In South America, total electron content (TEC) maps clearly showed the presence of the equatorial plasma bubbles, that, however, were not seen in data of Rate‐of‐TEC‐change index (ROTI). Global ROTI maps revealed intensive small‐scale irregularities at high latitudes in both hemispheres within the auroral region. In general, the ROTI disturbance “imaged” quite well the auroral oval boundaries. The most intensive ionospheric fluctuations were observed at low and mid‐latitudes over the Pacific Ocean. The storm also affected the positioning accuracy by GPS receivers: during the main phase of the storm, the precise point positioning error exceeded 0.5 m, which is more than five times greater as compared to quiet days. Key Points The strongest positive ionospheric storm occurred in Asian region at the end of the main phase of the storm driven by enhanced ExB drift In American region, several small‐scale positive and negative storms occurred at mid‐ and high‐latitudes, caused by a combination of drivers Satellite observations captured intensive ionospheric irregularities over the Pacific Ocean but also at high latitudes in South Hemisphere
ISSN:2169-9380
2169-9402
DOI:10.1029/2021JA029843