Japan Geoscience Union Meeting 2022

Presentation information

[E] Oral

P (Space and Planetary Sciences ) » P-EM Solar-Terrestrial Sciences, Space Electromagnetism & Space Environment

[P-EM13] Coupling Processes in the Atmosphere-Ionosphere System

Wed. May 25, 2022 10:45 AM - 12:15 PM 302 (International Conference Hall, Makuhari Messe)

convener:Huixin Liu(Earth and Planetary Science Division, Kyushu University SERC, Kyushu University), convener:Yuichi Otsuka(Institute for Space-Earth Environmental Research, Nagoya University), Loren Chang(Institute of Space Science, National Central University), convener:Yue Deng(University of Texas at Arlington), Chairperson:Masaki Tsutsumi(National Institute of Polar Research), Tatsuhiro Yokoyama(Kyoto University), Masaru Kogure(Kyushu University)


11:00 AM - 11:15 AM

[PEM13-20] Thermospheric Density Perturbations Produced by Traveling Atmospheric Disturbances during August 2005 Storm

*Kevin H Pham1, Binzheng Zhang2,1, Kareem Sorathia3, Tong Dang4, Wenbin Wang1, Viacheslav Merkin3, Huixin Liu5, Dong Lin1, Michael Wiltberger1, Jiuhou Lei4, Shanshan Bao6, Jeffrey Garretson3, Frank Toffoletto6, Adam Michael3, John Lyon7 (1.National Center for Atmospheric Research, 2.University of Hong Kong, 3.Johns Hopkins University, 4.University of Science and Technology of China, 5.Kyushu University, 6.Rice University, 7.Dartmouth College)

Keywords:Magnetosphere-Ionosphere-Thermosphere coupling, Traveling Atmospheric Disturbances, Whole Geospace Modeling

Thermospheric mass density perturbations are commonly observed during geomagnetic storms and fundamental to upper atmosphere dynamics, but the sources of these perturbations are not well understood. Large neutral density perturbations during storms greatly affect the drag experienced by low Earth orbit. We investigated the thermospheric density perturbations at all latitudes observed along the CHAMP and GRACE satellite trajectories during the 24-25 August 2005 geomagnetic storm. Observations show that large neutral density enhancements occurred not only at high latitudes, but also globally. Large density perturbations were seen in the equatorial regions away from the high-latitude, magnetospheric energy sources. We used the high-resolution Multiscale Atmosphere Geospace Environment (MAGE) model to simulate consecutive neutral density changes observed by satellites during the storm. The MAGE simulation, which resolved mesoscale high-latitude convection electric fields and field-aligned currents, and included physics-based specification of auroral precipitation, was contrasted with a standalone ionosphere-thermosphere simulation driven by a high-latitude electrodynamics empirical model. The comparison demonstrates that first-principles representations of highly dynamic and localized Joule heating events in a fully coupled whole geospace model is critical to accurately capture both generation and propagation of traveling atmospheric disturbances (TADs) that produce neutral density perturbations globally. The MAGE simulation shows that larger density peaks in the equatorial region observed by CHAMP and GRACE are the result of TADs generated at high-latitudes in both hemispheres, and intersect at low-latitudes. This study reveals the importance of investigating thermospheric density variations at all latitudes in a fully coupled geospace model with sufficiently high resolving power.