Litcius/Paper detail

Superfast precipitation of energetic electrons in the radiation belts of the Earth

Xiao‐Jia Zhang, Anton Artemyev, V. Angelopoulos, Ethan Tsai, Colin Wilkins, Satoshi Kasahara, D. Mourenas, Shoichiro Yokota, K. Keika, Tomoaki Hori, Yoshizumi Miyoshi, Iku Shinohara, Ayako Matsuoka

2022Nature Communications61 citationsDOIOpen Access PDF

Abstract

Energetic electron precipitation from Earth's outer radiation belt heats the upper atmosphere and alters its chemical properties. The precipitating flux intensity, typically modelled using inputs from high-altitude, equatorial spacecraft, dictates the radiation belt's energy contribution to the atmosphere and the strength of space-atmosphere coupling. The classical quasi-linear theory of electron precipitation through moderately fast diffusive interactions with plasma waves predicts that precipitating electron fluxes cannot exceed fluxes of electrons trapped in the radiation belt, setting an apparent upper limit for electron precipitation. Here we show from low-altitude satellite observations, that ~100 keV electron precipitation rates often exceed this apparent upper limit. We demonstrate that such superfast precipitation is caused by nonlinear electron interactions with intense plasma waves, which have not been previously incorporated in radiation belt models. The high occurrence rate of superfast precipitation suggests that it is important for modelling both radiation belt fluxes and space-atmosphere coupling.

Topics & Concepts

Van Allen radiation beltEarth (classical element)AstrobiologyElectronElectron precipitationPrecipitationEnvironmental sciencePhysicsAtmospheric sciencesRadiationAtomic physicsMeteorologyNuclear physicsMagnetosphereAstronomyPlasmaIonosphere and magnetosphere dynamicsAstro and Planetary ScienceSolar and Space Plasma Dynamics