Lower Hybrid Drift Waves During Guide Field Reconnection
Jongsoo Yoo, Jeong‐Young Ji, M. V. Ambat, Shan Wang, Hantao Ji, Jenson Lo, Bowen Li, Y. Ren, Jonathan Jara-Almonte, Li‐Jen Chen, W. Fox, M. Yamada, Andrew Alt, Aaron Goodman
Abstract
Abstract Generation and propagation of lower hybrid drift wave (LHDW) near the electron diffusion region (EDR) during guide field reconnection at the magnetopause is studied with data from the Magnetospheric Multiscale mission and a theoretical model. Inside the current sheet, the electron beta ( β e ) determines which type of LHDW is excited. Inside the EDR, where the electron beta is high ( β e ∼ 5 ), the long‐wavelength electromagnetic LHDW is observed propagating obliquely to the local magnetic field. In contrast, the short‐wavelength electrostatic LHDW, propagating nearly perpendicular to the magnetic field, is observed slightly away from the EDR, where β e is small ( ∼ 0.6). These observed LHDW features are explained by a local theoretical model, including effects from the electron temperature anisotropy, finite electron heat flux, electrostatics, and parallel current. The short‐wavelength LHDW is capable of generating significant drag force between electrons and ions.