Abstract
Abstract. During the main phase of geomagnetic storms, large positive ionospheric plasma density anomalies arise at middle and polar latitudes. A prominent example is the tongue of ionisation (TOI), which extends poleward from the dayside storm-enhanced density (SED) anomaly, often crossing the polar cap and streaming with the plasma convection flow into the nightside ionosphere. A fragmentation of the TOI anomaly contributes to the formation of polar plasma patches partially responsible for the scintillations of satellite positioning signals at high latitudes. To investigate this intense plasma anomaly, numerical simulations of plasma and neutral dynamics during the geomagnetic superstorm of 20 November 2003 are performed using the Thermosphere Ionosphere Electrodynamics Global Circulation Model (TIE-GCM) coupled with the statistical parameterisation of high-latitude plasma convection. The simulation results reproduce the TOI features consistently with observations of total electron content and with the results of ionospheric tomography, published previously by the authors. It is demonstrated that the fast plasma uplift, due to the electric plasma convection expanded to subauroral mid-latitudes, serves as a primary feeding mechanism for the TOI anomaly, while a complex interplay between electrodynamic and neutral wind transports is shown to contribute to the formation of a mid-latitude SED anomaly. This contrasts with published simulations of relatively smaller geomagnetic storms, where the impact of neutral dynamics on the TOI formation appears more pronounced. It is suggested that better representation of the high-latitude plasma convection during superstorms is needed. The results are discussed in the context of space weather modelling.
Highlights
In the course of a geomagnetic storm, large amounts of solar wind energy and momentum are deposited into the high-latitude ionosphere through the Joule dissipation of magnetosphere/ionosphere currents and auroral particle precipitation (Rodger et al, 2001)
The feeding mechanisms of the tongue of ionisation (TOI) anomaly have been analysed using the simulations of the geomagnetic superstorm of 20 November 2003, which have been conducted using the high-resolution version of the Thermosphere-Ionosphere Electrodynamics General Circulation Model (TIE-GCM) ionospheric circulation model with the Weimer parameterisation of high-latitude E × B plasma convection
The simulation results are compared to the International GNSS Services (IGS) total electron content (TEC) maps and to the results of ionospheric Global Navigation Satellite Systems (GNSS) tomography for this storm event, published earlier by the authors (Pokhotelov et al, 2008)
Summary
In the course of a geomagnetic storm, large amounts of solar wind energy and momentum are deposited into the high-latitude ionosphere through the Joule dissipation of magnetosphere/ionosphere currents and auroral particle precipitation (Rodger et al, 2001). Using an ultrahigh-resolution (0.6◦) version of the TIE-GCM model, Dang et al (2019) modelled the separation of the TOI anomaly into “double tongues” associated with morning and evening convection cells during the March 2013 storm event These recent modelling studies simulated relatively moderate geomagnetic storms. The 20 November 2003 storm provides an advantage of being an isolated event driven by a single coronal mass ejection (Zhang et al, 2007) It is among the largest geomagnetic storms observed by modern space/ground instrumentation, including Global Navigation Satellite Systems (GNSS). Studies of this storm using radars (Foster et al, 2005) and GNSS tomography (Pokhotelov et al, 2008) revealed the dynamics and 3D morphology of the TOI anomaly. Limitations of other ionospheric circulation models in reproducing the TOI anomaly are discussed, including the models currently used by space weather services
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