Please use this identifier to cite or link to this item: http://hdl.handle.net/2122/14383
Authors: Marchetti, Dedalo* 
De Santis, Angelo* 
Campuzano, Saioa Arquero* 
Soldani, Maurizio* 
Piscini, Alessandro* 
Sabbagh, Dario* 
Cianchini, Gianfranco* 
Perrone, Loredana* 
Orlando, Martina* 
Title: Swarm Satellite Magnetic Field Data Analysis Prior to 2019 Mw = 7.1 Ridgecrest (California, USA) Earthquake
Journal: Geosciences 
Series/Report no.: 12/10(2020)
Publisher: MDPI
Issue Date: Dec-2020
DOI: 10.3390/geosciences10120502
Keywords: Swarm
earthquakes
Ridgecrest
ionospheric seismo-induced disturbances
earth magnetic field
Abstract: This work presents an analysis of the ESA Swarm satellite magnetic data preceding the Mw = 7.1 California Ridgecrest earthquake that occurred on 6 July 2019. In detail, we show the main results of a procedure that investigates the track-by-track residual of the magnetic field data acquired by the Swarm constellation from 1000 days before the event and inside the Dobrovolsky’s area. To exclude global geomagnetic perturbations, we select the data considering only quiet geomagnetic field time, defined by thresholds on Dst and ap geomagnetic indices, and we repeat the same analysis in two comparison areas at the same geomagnetic latitude of the Ridgecrest earthquake epicentre not affected by significant seismicity and in the same period here investigated. As the main result, we find some increases of the anomalies in the Y (East) component of the magnetic field starting from about 500 days before the earthquake. Comparing such anomalies with those in the validation areas, it seems that the geomagnetic activity over California from 222 to 168 days before the mainshock could be produced by the preparation phase of the seismic event. This anticipation time is compatible with the Rikitake empirical law, recently confirmed from Swarm satellite data. Furthermore, the Swarm Bravo satellite, i.e., that one at highest orbit, passed above the epicentral area 15 min before the earthquake and detected an anomaly mainly in the Y component. These analyses applied to the Ridgecrest earthquake not only intend to better understand the physical processes behind the preparation phase of the medium-large earthquakes in the world, but also demonstrate the usefulness of a satellite constellation to monitor the ionospheric activity and, in the future, to possibly make reliable earthquake forecasting.
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