Abstract
A statistical study to determine the influence of geomagnetic disturbances on the ionosphere across the dawn terminator at subauroral and middle latitudes is performed, based on the vertical electron density profiles measured by the GPS Occultation Experiment aboard the FORMOSAT-3/COSMIC satellites from August 2006 to July 2009. Three ranges of solar zenith angles are adopted to characterize transitions between the pre- and post-dawn ionosphere. Results indicate opposing plasma density effects at the darkened and sunlit locations between 50° and 65° magnetic latitude ( λ m ). The darkened topside ionosphere features density increases associated with geomagnetic activity, while density reductions mark its sunlit counterpart. The average electron peak density in the F2 region can increase by up to 44% in the darkened ionosphere and decrease by up to 20% in the sunlit ionosphere as Kp changes from 0–1 to 4–5. In the λ m = 55°–65° range, the dominant contributors to the density perturbation are auroral electron precipitation for the darkened region and enhanced penetration electric fields for the sunlit region, with the transition occurring across the terminator local times. Dominance shifts first to electric fields at 50°–55°, then to aurora-induced neutral wind at 45°–50°, suggesting that during disturbed times electric fields seldom penetrate below λ m = 50°. Findings presented in this statistical study should contribute to the study of space weather and the understanding of non-local influences of geomagnetic disturbances on topside dynamics.
Highlights
As human activities increasingly rely on space-based technology, accurate prediction of the influence of geomagnetic disturbances on the topside ionosphere has become ever more important
This study examines the statistical properties of perturbations in vertical electron density profiles (EDPs) observed near the dawn meridian at subauroral latitudes due to geomagnetic activity
We have performed a statistical study on three years of ionospheric vertical EDPs observed during solar minimum by the GPS occultation experiment (GOX) instrument aboard the F3C satellites, focusing on the effects of geomagnetic activity at subauroral latitudes around the dawn hours
Summary
As human activities increasingly rely on space-based technology, accurate prediction of the influence of geomagnetic disturbances on the topside ionosphere has become ever more important. Reported observations showed that at these latitudes the ionosphere manifests positive and negative plasma density perturbations during periods of geomagnetic activity The observed positive and negative perturbations are responses to multiple driving mechanisms associated with geomagnetic disturbances. Positive density effects may be due to traveling atmospheric/ionospheric disturbances (Prölss & Jung, 1978; Cai et al, 2012), variations in the global wind circulation (Jones & Rishbeth, 1971; Ngwira et al, 2012), expansion of the region. Physical mechanisms responsible for density perturbations during periods of enhanced geomagnetic activity were mostly identified through case studies of individual storm or substorm events By tracking plasma properties at given ionospheric locations throughout disturbed periods, the case-study approach can reveal critical details about the local changes that allow investigators to identify causative physical mechanisms. Case studies are essential for identifying and quantifying the diverse
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