Relativistic Electron Precipitation by EMIC Waves: Importance of Nonlinear Resonant Effects

Veronika S. Grach; Anton V. Artemyev; Andrei G. Demekhov; Xiao‐Jia Zhang; Jacob Bortnik; Vassilis Angelopoulos; Rumi Nakamura; Ethan Tsai; Colin Wilkins; Owen W. Roberts

doi:10.1029/2022GL099994

Geophysical Research Letters (Sep 2022)

Relativistic Electron Precipitation by EMIC Waves: Importance of Nonlinear Resonant Effects

Veronika S. Grach,
Anton V. Artemyev,
Andrei G. Demekhov,
Xiao‐Jia Zhang,
Jacob Bortnik,
Vassilis Angelopoulos,
Rumi Nakamura,
Ethan Tsai,
Colin Wilkins,
Owen W. Roberts

Affiliations

Veronika S. Grach: Institute of Applied Physics Russian Academy of Sciences Nizhny Novgorod Russia
Anton V. Artemyev: University of California Los Angeles CA USA
Andrei G. Demekhov: Institute of Applied Physics Russian Academy of Sciences Nizhny Novgorod Russia
Xiao‐Jia Zhang: University of California Los Angeles CA USA
Jacob Bortnik: University of California Los Angeles CA USA
Vassilis Angelopoulos: University of California Los Angeles CA USA
Rumi Nakamura: Space Research Institute Austrian Academy of Science Graz Austria
Ethan Tsai: University of California Los Angeles CA USA
Colin Wilkins: University of California Los Angeles CA USA
Owen W. Roberts: Space Research Institute Austrian Academy of Science Graz Austria

DOI: https://doi.org/10.1029/2022GL099994
Journal volume & issue: Vol. 49, no. 17
pp. n/a – n/a

Abstract

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Abstract Relativistic electron losses in Earth's radiation belts are usually attributed to electron resonant scattering by electromagnetic waves. One of the most important wave modes for such scattering is the electromagnetic ion cyclotron (EMIC) mode. Within the quasi‐linear diffusion framework, the cyclotron resonance of relativistic electrons with EMIC waves results in very fast electron precipitation to the atmosphere. However, wave intensities often exceed the threshold for nonlinear resonant interaction, and such intense EMIC waves have been shown to transport electrons away from the loss cone due to the force bunching effect. In this study we investigate if this transport can block electron precipitation. We combine test particle simulations, low‐altitude observations of EMIC‐driven electron precipitation by the Electron Losses and Fields Investigations mission, and ground‐based EMIC observations. Comparing simulations and observations, we show that, despite the low pitch‐angle electrons being transported away from the loss cone, the scattering at higher pitch angles results in the loss cone filling and electron precipitation.

Published in Geophysical Research Letters

ISSN: 0094-8276 (Print); 1944-8007 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Science: Physics: Geophysics. Cosmic physics
Website: https://agupubs.onlinelibrary.wiley.com/journal/19448007

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