Satellite based detection of pre-earthquake thermal anomaly, co-seismic deformation and source parameter modelling of past earthquakes

Abstract

The presented work brings satellite-based detection of pre-earthquake transient thermal anomaly and coseismic deformation mechanism using InSAR (SAR Interferometry) observations of the two major earthquakes that occurred recently (the Iran-Iraq border earthquake of Nov. 12, 2017 (Mw 7.3) and the New Mirpur, Pakistan earthquake of 24th Sept. 2019 (Mw 5.4)). Near Iran-Iraq border earthquake, a rise of 4–6 ​°C from the normal temperature in both day and night Land Surface Temperature (LST) maps along the SW part of the fault is observed. In case of the New Mirpur, Pakistan earthquake, a rise of 3–5 ​°C from normal temperature in both day and night LST maps around the SSW and NW side of the epicenter is observed. Further, Sentinel-1A microwave satellite data employing InSAR technique have been used to estimate co-seismic ground deformations and fault geometry and slip distribution of both earthquakes. The results show that both events occurred due to blind reverse fault mechanism dipping NE with shallow dip. The weightage of strike slip component and dip slip component is more or less equal to each other in total slip distribution for Iran-Iraq border earthquake. Similarly, New Mirpur, Pakistan earthquake have more strike slip components than dip slip components in the weightage in total slip distribution. Considerable number of aftershocks have also occurred in the regions as estimated by coulomb static stress along the SW side of the fault geometry of Iran-Iraq border earthquake and for New Mirpur, Pakistan earthquake, along the SSW, NW, and east side of the fault geometry. The correlation between high stress regions before and after the occurrence of earthquakes using thermal anomaly map and Coulomb static stress map has been also observed.