A numerical model of the ionosphere, including the E-region above EISCAT
Abstract
It has been previously demonstrated that a two-ion (O<sup>+</sup> and H<sup>+</sup>) 8-moment time-dependent fluid model was able to reproduce correctly the ionospheric structure in the altitude range probed by the EISCAT-VHF radar. In the present study, the model is extended down to the E-region where molecular ion chemistry (NO<sup>+</sup> and O<sup>+</sup><sub>2</sub>, essentially) prevails over transport; EISCAT-UHF observations confirmed previous theoretical predictions that during events of intense <strong>E</strong>×<strong>B</strong> induced convection drifts, molecular ions (mainly NO<sup>+</sup>) predominate over O<sup>+</sup> ions up to altitudes of 300 km. In addition to this extension of the model down to the E-region, the ionization and heating resulting from both solar insolation and particle precipitation is now taken into account in a consistent manner through a complete kinetic transport code. The effects of <strong>E</strong>×<strong>B</strong> induced convection drifts on the E- and F-region are presented: the balance between O<sup>+</sup> and NO<sup>+</sup> ions is drastically affected; the electric field acts to deplete the O<sup>+</sup> ion concentration. The [NO<sup>+</sup>]/[O<sup>+</sup>] transition altitude varies from 190 km to 320 km as the perpendicular electric field increases from 0 to 100 mV m<sup>-1</sup>. An interesting additional by-product of the model is that it also predicts the presence of a noticeable fraction of N<sup>+</sup> ions in the topside ionosphere in good agreement with Retarding Ion Mass Spectrometer measurements onboard Dynamic Explorer.
