University of Tehran Press Journal of the Earth and Space Physics 2538-371X 47 4 2022 01 21 On the Propagation of VLF Electric Field Emissions Associated with Earthquakes in the Middle Layer of the Earth Crust On the Propagation of VLF Electric Field Emissions Associated with Earthquakes in the Middle Layer of the Earth Crust 1 13 81560 10.22059/jesphys.2021.298662.1007196 FA Sarita Sharma Research Scholar, Department of Physics, Institute of Applied Sciences & Humanities, GLA University, Mathura, India Raj Pal Singh Professor, Department of Physics, Institute of Applied Sciences & Humanities, GLA University, Mathura, India Journal Article 2020 03 05 An ensemble of elementary radiators is generated on the basement rock because of the applied stresses in the preparation zone of the earthquakes in the earth crust. Considering such an ‘ensemble’ as the source of electromagnetic signals, the strength of the electric field is estimated at different distances and frequencies laying in range (3 – 27 kHz) at three different conductivities of the crustal layers (10<sup>-8</sup>, 10<sup>-9</sup>, 10<sup>-10 </sup>S/m). The results of the computation are presented in this paper. Moreover, propagation distances for the seismogenic VLF emissions have also been calculated in the frequency band (3 – 27 kHz) at the conductivities laying in the range (10<sup>-8 </sup>- 10<sup>-10 </sup>S/m) within the limit of detectability of measuring instruments (10<sup>-7</sup> V/m). It is observed that these distances increase with the decrease of conductivity of the middle layer of crust. Furthermore, theoretical results of computations are verified from the experimental observations of the seismic event that occurred at the distance of 698 km from the observing station at Chaumuhan Mathura (Geographic lat. 27.49<sup>0</sup>N, long. 77.67<sup>0</sup>E). In addition to this, the generation and propagation mechanisms of seismo-electromagnetic radiations have also been discussed briefly. An ensemble of elementary radiators is generated on the basement rock because of the applied stresses in the preparation zone of the earthquakes in the earth crust. Considering such an ‘ensemble’ as the source of electromagnetic signals, the strength of the electric field is estimated at different distances and frequencies laying in range (3 – 27 kHz) at three different conductivities of the crustal layers (10<sup>-8</sup>, 10<sup>-9</sup>, 10<sup>-10 </sup>S/m). The results of the computation are presented in this paper. Moreover, propagation distances for the seismogenic VLF emissions have also been calculated in the frequency band (3 – 27 kHz) at the conductivities laying in the range (10<sup>-8 </sup>- 10<sup>-10 </sup>S/m) within the limit of detectability of measuring instruments (10<sup>-7</sup> V/m). It is observed that these distances increase with the decrease of conductivity of the middle layer of crust. Furthermore, theoretical results of computations are verified from the experimental observations of the seismic event that occurred at the distance of 698 km from the observing station at Chaumuhan Mathura (Geographic lat. 27.49<sup>0</sup>N, long. 77.67<sup>0</sup>E). In addition to this, the generation and propagation mechanisms of seismo-electromagnetic radiations have also been discussed briefly. Attenuation earthquake Earth crust Radiating dipole VLF waves https://jesphys.ut.ac.ir/article_81560_98336acc20244f1cff325abdf96a4486.pdf