Effect of 21 June 2020 solar eclipse on the ionosphere using VLF and GPS observations and modeling

Abstract

A solar eclipse event provides a great opportunity to examine the behavioral concept of the ionospheric electron density (Ne) variability in the low latitude region. The current work presents our outcomes from the simultaneous assessment of Tweeks (radio atmospherics) and radio signals (fixed frequency of the transmitter’s signal) from multifarious VLF transmitters observed at Varanasi (Geog. Lat. 25.270N, Geog. Long. 82.980 E, Geomag. Lat. 140 550N). To find the presence of disturbances in the ionosphere Global Positioning System (GPS) data at Hyderabad (geog. lat. 170 20/ N, long. 780 30/ E) and Bangalore (geog. lat. 120 58/ N, long. 770 33/ E) is also analyzed during the period of the solar eclipse on 21 June 2020. As the Sun was eclipsed, the nighttime phenomenon of ‘Tweeks’ was also observed in the daytime through the annular solar eclipse due to nighttime conditions as the solar disc was dusked. Tweek analysis shows the variation in the ionospheric reflection heights (_8–11 km) and electron density (_3–2 cm_3) in the D-region during the eclipse. The reflection height of the D-region ionosphere increases from _84 km and goes to _95 km and then decreases to _87 km. Electron concentration (electron density) decreased throughout the eclipse from 24 cm_3 to 21 cm_3 and then increases to 23 cm _3. Eclipse-imposed modifications in VLF transmitter’s (HWU and NWC) signals displays an average change (decrease) of 2.8 dB and 0.8 dB in the signal strength of 18.3 kHz (HWU) and 19.8 kHz (NWC) transmitters respectively and a rise in virtual reference height (H0) and sharpness factor (b), as compared with normal days. The de-trended value of total electron content (DTEC) variations at both stations clearly shows the presence of travelling ionospheric disturbances (TIDs) having wave-like features. The Fast Fourier Transform (FFT) analysis shows that periodicity at both the station lies in two regimes one belongs to a period between 20 and 50 min and the other belongs to 50–90 min indicating such oscillation observed in the ionosphere are induced by atmospheric gravity waves (AGWs) generated during the period of the solar eclipse.