Investigation of the geomagnetic storms’ impact on low-latitude ionosphere: case studies of October 2003 and March 2015 events

Hammed  Adeniyi Lawal; Isreal Leke  Elijah; Edwin Beshel  Ayabie; Yusuf Bello; Joseph Alao; Innocent Davidson

doi:10.61298/pnspsc.2025.2.155

Authors

Hammed Adeniyi Lawal
hadelawal@yahoo.co.uk
Department of Physics, Air Force Institute of Technology, Nigerian Air Force Base, Nigeria https://orcid.org/0000-0002-8905-9812
Isreal Leke Elijah Department of Physics, Air Force Institute of Technology, Nigerian Air Force Base, Nigeria
Edwin Beshel Ayabie Department of Physics, Air Force Institute of Technology, Nigerian Air Force Base, Nigeria
Yusuf Ayoola Bello Department of Physics, Air Force Institute of Technology, Nigerian Air Force Base, Nigeria
Joseph O. Alao Department of Physics, Air Force Institute of Technology, Nigerian Air Force Base, Nigeria
Innocent E. Davidson Department of Electrical, Electronic and Computer Engineering, French-South African Institute of Technology (F’SATI), Cape Peninsula University of Science and Technology, Cape Town, South Africa

Keywords:

Geomagnetic storms, Low latitude ionosphere, Ionospheric composition

Abstract

Geomagnetic storms can significantly impact the Earth's upper atmosphere known as the ionosphere used for communication and navigation, particularly at low latitudes. This study examines the effects of two major geomagnetic storms on the low-latitude ionosphere that occurred during October 2003 and March 2015. In the analysis of the two events, data from NASA Space Physics data resources, Omni web, were analysed. Our analysis of the electron density, temperature, and ion composition data reveals significant disturbances in the ionosphere during both storms. The October 2003 storm caused a decrease in electron density and an increase in temperature, while the March 2015 storm had a more moderate impact. Our results highlight the importance of understanding geomagnetic storms' effects on the low-latitude ionosphere, particularly for mitigating their impacts on radio communication, navigation, and satellite operations. This study contributes to our understanding of geomagnetic storms' effects on the ionosphere and provides valuable insights for future research and applications.

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REFERENCES

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Investigation of the geomagnetic storms’ impact on low-latitude ionosphere: case studies of October 2003 and March 2015 events

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