Ionospheric Disturbances Observed Following the Ridgecrest Earthquake of 4 July 2019 in California, USA

Ionospheric Disturbances Observed Following the Ridgecrest Earthquake of 4 July 2019 in California, USA

Earthquakes are known to generate disturbances in the ionosphere. Such disturbances, referred to as co-seismic ionospheric disturbances, or ionoquakes, were previously reported for large earthquakes with magnitudes Mw≥ 6.6. This paper reports ionoquakes associated with the Ridgecrest earthquakes of...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Vol. 14; no. 1; p. 188
Main Authors: Sanchez, Saul A., Kherani, Esfhan A., Astafyeva, Elvira, de Paula, Eurico R.
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-01-2022
MDPI
Subjects:
acoustic gravity waves
Aftershocks
Earth Sciences
Earthquakes
GNSS-TEC
Ground motion
Ionosphere
Mathematical models
Remote sensing
Satellites
Sciences of the Universe
Seismic activity
seismo–atmosphere–ionosphere coupling
Total Electron Content
Traveling ionospheric disturbances
Velocity
United States > US
California
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Summary:Earthquakes are known to generate disturbances in the ionosphere. Such disturbances, referred to as co-seismic ionospheric disturbances, or ionoquakes, were previously reported for large earthquakes with magnitudes Mw≥ 6.6. This paper reports ionoquakes associated with the Ridgecrest earthquakes of magnitude (Mw=6.4), that occurred on 4 July 2019 in California, USA. The ionoquakes manifested in total electron content (TEC) in the form of traveling ionospheric disturbances (TIDs) within 1 h from the mainshock onset. These seismic-origin TIDs have unique wave characteristics that distinguish them from TIDs of non-seismic origin arising from a moderate geomagnetic activity on the same day. Moreover, in the space-time domain of the detection of seismic-origin TIDs, TIDs are absent on the day before and day after the earthquake day. Their spectral characteristics relate them to the Earth’s normal modes and atmospheric resonance modes. We found the ground velocity associated with the mainshock, rather than the ground displacement, satisfies the threshold criteria for detectable ionoquakes in TEC measurements. Numerical simulation suggested that the coupled seismo–atmosphere–ionosphere (SAI) dynamics energized by the atmospheric waves are responsible for the generation of ionoquakes. This study’s findings demonstrate the potential of using TEC measurement to detect the ionospheric counterparts of moderate earthquakes.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs14010188