Abstract
Abstract. The systematic study of ionospheric storms has been conducted primarily with groundbased data from the Northern Hemisphere. Significant progress has been made in defining typical morphology patterns at all latitudes; mechanisms have been identified and tested via modeling. At higher mid-latitudes (sites that are typically sub-auroral during non-storm conditions), the processes that change significantly during storms can be of comparable magnitudes, but with different time constants. These include ionospheric plasma dynamics from the penetration of magnetospheric electric fields, enhancements to thermospheric winds due to auroral and Joule heating inputs, disturbance dynamo electrodynamics driven by such winds, and thermospheric composition changes due to the changed circulation patterns. The ~12° tilt of the geomagnetic field axis causes significant longitude effects in all of these processes in the Northern Hemisphere. A complementary series of longitude effects would be expected to occur in the Southern Hemisphere. In this paper we begin a series of studies to investigate the longitudinal-hemispheric similarities and differences in the response of the ionosphere's peak electron density to geomagnetic storms. The ionosonde stations at Wallops Island (VA) and Hobart (Tasmania) have comparable geographic and geomagnetic latitudes for sub-auroral locations, are situated at longitudes close to that of the dipole tilt, and thus serve as our candidate station-pair choice for studies of ionospheric storms at geophysically-comparable locations. They have an excellent record of observations of the ionospheric penetration frequency (foF2) spanning several solar cycles, and thus are suitable for long-term studies. During solar cycle #20 (1964–1976), 206 geomagnetic storms occurred that had Ap≥30 or Kp≥5 for at least one day of the storm. Our analysis of average storm-time perturbations (percent deviations from the monthly means) showed a remarkable agreement at both sites under a variety of conditions. Yet, small differences do appear, and in systematic ways. We attempt to relate these to stresses imposed over a few days of a storm that mimic longer term morphology patterns occurring over seasonal and solar cycle time spans. Storm effects versus season point to possible mechanisms having hemispheric differences (as opposed to simply seasonal differences) in how solar wind energy is transmitted through the magnetosphere into the thermosphere-ionosphere system. Storm effects versus the strength of a geomagnetic storm may, similarly, be related to patterns seen during years of maximum versus minimum solar activity.
Highlights
The response of the ionosphere to increases in geomagnetic activity has been a central topic of study since the earliest days of solar-terrestrial space science
Defining precisely what constitutes a sub-auroral site is fraught with difficulties, so here we offer a broad set of attributes: (1) under quiet conditions, the L=2–3 domain is always within the plasmasphere during the daytime hours, but might include plasmapause/ionospheric trough locations during portions of the night near L=3 (∼55◦ magnetic latitude)
In this attempt to test our understanding of ionospheric storm processes as truly global phenomena, we introduced the concept of geophysically-equivalent sites in each hemisphere and produced average storm patterns under a variety of conditions
Summary
The response of the ionosphere to increases in geomagnetic activity has been a central topic of study since the earliest days of solar-terrestrial space science. The morphology patterns of ionospheric storms at middle and low latitudes are rather well known, and the dominant mechanisms responsible for them have been identified and modeled. A significant number of case studies have been published, many dealing with strong storms that show the extremes capable of being achieved by specific mechanisms. An important message to come from all of these past studies is that there are no new physical mechanisms that appear within the F-layer only during storms, or that unique scalings or saturation phenomena occur only during storms
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