Abstract
The technique of spherical elementary current systems (SECS) is a powerful way to determine ionospheric and field-aligned currents (FAC) from magnetic field measurements made by low-Earth-orbiting satellites, possibly in combination with magnetometer arrays on the ground. The SECS method consists of two sets of basis functions for the ionospheric currents: divergence-free (DF) and curl-free (CF) components, which produce poloidal and toroidal magnetic fields, respectively. The original CF SECS are only applicable at high latitudes, as they build on the assumption that the FAC flow radially into or out of the ionosphere. The FAC at low and middle latitudes are far from radial, which renders the method inapplicable at these latitudes. In this study, we modify the original CF SECS by including FAC that flow along dipolar field lines. This allows the method to be applied at all latitudes. We name this method dipolar elementary current systems (DECS). Application of the DECS to synthetic data, as well as Swarm satellite measurements are carried out, demonstrating the good performance of this method, and its applicability to studies of ionospheric current systems at low and middle latitudes.
Highlights
At middle and low magnetic latitudes the main driver of ionospheric currents is the neutral wind and the collisional interaction between the charged and neutral particles
Two prominent current systems considered in this work are the interhemispheric field-aligned currents (IHFAC) and the equatorial electrojet (EEJ)
In order to avoid the assumption of strict anti-symmetry between the northern and southern hemispheres, the CF part of the Swarm/dipolar elementary current systems (DECS) analysis is done separately for each hemisphere
Summary
At middle and low magnetic latitudes the main driver of ionospheric currents is the neutral wind and the collisional interaction between the charged and neutral particles. The neutral wind field itself is driven by solar heating and solar and lunar atmospheric tides. A comprehensive review of the middle and low-latitude current systems is given by Yamazaki and Maute (2016). The overall largescale current system forms two oppositely directed vortices at the northern and southern hemisphere on the dayside. This is named solar-quiet (Sq) current system, as it shows a strong dependence on solar local time and is present even during geomagnetically quiet conditions.
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