Remote Sensing (Jan 2024)

The Turkey Earthquake Induced Equatorial Ionospheric Current Disturbances on 6 February 2023

  • Kedeng Zhang,
  • Hui Wang,
  • Hao Xia,
  • Wenbin Wang,
  • Jing Liu,
  • Shunrong Zhang,
  • Yaqi Jin

DOI
https://doi.org/10.3390/rs16020272
Journal volume & issue
Vol. 16, no. 2
p. 272

Abstract

Read online

An earthquake is a seismic event resulting from a sudden release of energy in the lithosphere, which produces waves that can propagate through the atmosphere into the ionosphere, causing ionospheric disturbances, and excites an additional electric field in the lower ionosphere. Two large-scale traveling ionospheric disturbances (LSTIDs) at daytime Turkey longitudes were found, with phase speeds of 534 and 305 m/s, respectively, after the second strong earthquake at 10:24 UT on 6 February 2023. During strong earthquakes, the equatorial ionospheric currents including the E-region equatorial electrojet (EEJ) and F-region ionospheric radial current (IRC) might be perturbed. At the Tatuoca station in Brazil, we observed a stronger-than-usual horizontal magnetic field associated with the EEJ, with a magnitude of ~100 nT. EEJ perturbations are mainly controlled by neutral winds, especially zonal winds. In the equatorial F-region, a wave perturbation of the IRC was caused by a balance of the electric field generated by the zonal winds at ~15° MLat, the F-region local winds driven by atmospheric resonance, and the additional polarization electric field. Our findings better the understanding of the complex interplay between seismic events and ionospheric current disturbances.

Keywords