Driver of Energetic Electron Precipitation in the Vicinity of Ganymede

W. Li; Q. Ma; X.‐C. Shen; X.‐J. Zhang; B. H. Mauk; G. Clark; F. Allegrini; W. S. Kurth; G. B. Hospodarsky; A. Sulaiman; T. A. Nordheim; S. J. Bolton

doi:10.1029/2022GL101555

Geophysical Research Letters (Mar 2023)

Driver of Energetic Electron Precipitation in the Vicinity of Ganymede

W. Li,
Q. Ma,
X.‐C. Shen,
X.‐J. Zhang,
B. H. Mauk,
G. Clark,
F. Allegrini,
W. S. Kurth,
G. B. Hospodarsky,
A. Sulaiman,
T. A. Nordheim,
S. J. Bolton

Affiliations

W. Li: Center for Space Physics Boston University Boston MA USA
Q. Ma: Center for Space Physics Boston University Boston MA USA
X.‐C. Shen: Center for Space Physics Boston University Boston MA USA
X.‐J. Zhang: Department of Earth, Planetary, and Space Sciences University of California, Los Angeles Los Angeles CA USA
B. H. Mauk: The Johns Hopkins University Applied Physics Laboratory Laurel MD USA
G. Clark: The Johns Hopkins University Applied Physics Laboratory Laurel MD USA
F. Allegrini: Southwest Research Institute San Antonio TX USA
W. S. Kurth: University of Iowa Iowa City IA USA
G. B. Hospodarsky: University of Iowa Iowa City IA USA
A. Sulaiman: School of Physics & Astronomy University of Minnesota Twin Cities Minneapolis MN USA
T. A. Nordheim: Jet Propulsion Laboratory California Institute of Technology Pasadena CA USA
S. J. Bolton: Southwest Research Institute San Antonio TX USA

DOI: https://doi.org/10.1029/2022GL101555
Journal volume & issue: Vol. 50, no. 6
pp. n/a – n/a

Abstract

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Abstract The driver of energetic electron precipitation into Ganymede's atmosphere has been an outstanding open problem. During the Juno flyby of Ganymede on 7 June 2021, Juno observed significant downward‐going electron fluxes inside the bounce loss cone of Ganymede's polar magnetosphere. Concurrently, Juno detected intense whistler‐mode waves, both in the quasi‐parallel and highly oblique directions with respect to the magnetic field line. We use quasi‐linear model to quantify energetic electron precipitation driven by quasi‐parallel and very oblique whistler‐mode waves, respectively, in the vicinity of Ganymede. The data‐model comparison indicates that in Ganymede's lower‐latitude (higher‐latitude) polar region, quasi‐parallel whistler‐mode waves play a dominant role in precipitating higher‐energy electrons above ∼100s eV (∼1 keV), whereas highly oblique waves are important for precipitating lower‐energy electrons below 100s eV (∼1 keV). Our result provides new evidence of whistler‐mode waves as a potential primary driver of precipitating energetic electrons into Ganymede's atmosphere.

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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