Abstract
During auroral substorms the electric currents flowing in the ionosphere change rapidly and a large amount of energy is dissipated in the auroral ionosphere. An important part of the auroral current system are the auroral electrojets whose profiles can be estimated from magnetic field measurements from Low Earth Orbit satellites. In this paper we combine electrojet data derived from the Swarm satellite mission of ESA with the substorm database derived from the SuperMAG ground magnetometer network data. We organize the electrojet data in relation to the location and time of the onset and obtain statistics for the development of the integrated current and latitudinal location for the auroral electrojets relative to the onset. The major features of the behaviour of the westward electrojet are found to be in accordance with earlier studies of field aligned currents and ground magnetometer observations of substorm time statistics. In addition we show that after the onset the latitudinal location of the maximum of the westward electrojet determined from Swarm satellite data is mostly located close to the SuperMAG onset latitude in the local time sector of the onset regardless of where the onset happens. We also show that the SuperMAG onset corresponds to a strengthening of the order of 100 kA in the amplitude of the median of the westward integrated current in the Swarm data from 15 minutes before to 15 minutes after the onset.
Highlights
Ionospheric electric currents give rise to a variety of space weather effects that influence the performance and reliability of 15 space-borne and ground-based technological systems
We have shown that the auroral electrojet characteristics derived from Swarm AEBS data products is organized in a way which can be interpreted to be consistent with earlier observations of bulge-type substorm expansion and large scale substorm current wedge (SCW) development
The data consists of separate oval crossings from different magnetic local time (MLT)-sectors of substorm current systems, 285 the resulting distribution, the resulting distribution agrees with earlier studies of the time development of substorms at least in the 15 minute timescale used in this study
Summary
Ionospheric electric currents give rise to a variety of space weather effects that influence the performance and reliability of 15 space-borne and ground-based technological systems. Problems in ground-based systems occur for instance due to geomagnetically induced currents (GIC) in technological conductor systems such as power grids (Pirjola, 2000, 2002). Substorms are a major source of GIC (Viljanen et al, 2006) because the geoelectric fields and induced currents are linked to rapid changes of the ionospheric currents which are highly variable during substorms. A better understanding of the temporal and spatial structure of the high latitude ionospheric currents during substorms and in particular a better description of their contribution 20 for a given time and location is of great importance for advances in fundamental space research and regarding practical applications.
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