Trapped and Leaking Energetic Particles in Injection Flux Tubes of Saturn's Magnetosphere

Ze‐Fan Yin; Yi‐Xin Sun; Xu‐Zhi Zhou; Dong‐Xiao Pan; Zhong‐Hua Yao; Chao Yue; Ze‐Jun Hu; Elias Roussos; Michel Blanc; Hai‐Rong Lai; Qiu‐Gang Zong

doi:10.1029/2023GL105687

Geophysical Research Letters (Oct 2023)

Trapped and Leaking Energetic Particles in Injection Flux Tubes of Saturn's Magnetosphere

Ze‐Fan Yin,
Yi‐Xin Sun,
Xu‐Zhi Zhou,
Dong‐Xiao Pan,
Zhong‐Hua Yao,
Chao Yue,
Ze‐Jun Hu,
Elias Roussos,
Michel Blanc,
Hai‐Rong Lai,
Qiu‐Gang Zong

Affiliations

Ze‐Fan Yin: School of Earth and Space Sciences Peking University Beijing China
Yi‐Xin Sun: School of Earth and Space Sciences Peking University Beijing China
Xu‐Zhi Zhou: School of Earth and Space Sciences Peking University Beijing China
Dong‐Xiao Pan: School of Geophysics and Information Technology China University of Geosciences Beijing China
Zhong‐Hua Yao: Key Laboratory of Earth and Planetary Physics Institute of Geology and Geophysics Chinese Academy of Sciences Beijing China
Chao Yue: School of Earth and Space Sciences Peking University Beijing China
Ze‐Jun Hu: MNR Key Laboratory for Polar Science Polar Research Institute of China Shanghai China
Elias Roussos: Max Planck Institute for Solar System Research Göttingen Germany
Michel Blanc: Institut de Recherche en Astrophysique et Planétologie Toulouse France
Hai‐Rong Lai: School of Atmospheric Sciences Sun Yat‐sen University Zhuhai China
Qiu‐Gang Zong: School of Earth and Space Sciences Peking University Beijing China

DOI: https://doi.org/10.1029/2023GL105687
Journal volume & issue: Vol. 50, no. 19
pp. n/a – n/a

Abstract

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Abstract In Saturn's magnetosphere, the radially‐inward transport of magnetic fluxes is usually carried by localized flux tubes with sharply‐enhanced equatorial magnetic fields. The flux tubes also bring energetic particles inward, which are expected to drift azimuthally and produce energy‐dispersive signatures. Spacecraft observations, however, indicate the occurrence of energy‐dispersionless signatures for perpendicular‐moving particles. These unexpected features are attributed to the sharp magnetic gradient at the edge of the flux tubes, which significantly modifies the drift trajectories of perpendicular‐moving particles to enable their trapping motion within the flux tubes. The bouncing particles are less affected by the gradient, and therefore, still display energy‐dispersive signatures. It is the distinct particle behavior, together with different spacecraft traversal paths, that underlies the observational diversity. The results improve our understanding of particle dynamics in the magnetospheres of giant planets and indicate that pitch‐angle information should be considered in the extraction of flux‐tube properties from energetic particle observations.

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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