Closed Fluxtubes and Dispersive Proton Conics at Jupiter's Polar Cap

J R Szalay; G Clark; G Livadiotis; D J McComas; D G Mitchell; J S Rankin; A H Sulaiman; F Allegrini; F Bagenal; R W Ebert; G R Gladstone; W S Kurth; B H Mauk; P W Valek; R J Wilson; S J Bolton

doi:10.1029/2022GL098741

Closed Fluxtubes and Dispersive Proton Conics at Jupiter's Polar Cap

Geophys Res Lett. 2022 May 16;49(9):e2022GL098741. doi: 10.1029/2022GL098741. Epub 2022 Apr 29.

Authors

J R Szalay¹, G Clark², G Livadiotis¹, D J McComas¹, D G Mitchell², J S Rankin¹, A H Sulaiman³, F Allegrini^{4

5}, F Bagenal⁶, R W Ebert^{4

5}, G R Gladstone⁴, W S Kurth³, B H Mauk², P W Valek⁴, R J Wilson⁶, S J Bolton⁴

Affiliations

¹ Department of Astrophysical Sciences Princeton University Princeton NJ USA.
² The Johns Hopkins University Applied Physics Laboratory Laurel MD USA.
³ University of Iowa Iowa IA USA.
⁴ Southwest Research Institute San Antonio TX USA.
⁵ Department of Physics and Astronomy University of Texas at San Antonio San Antonio TX USA.
⁶ Laboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder CO USA.

Abstract

Two distinct proton populations are observed over Jupiter's southern polar cap: a ∼1 keV core population and ∼1-300 keV dispersive conic population at 6-7 R_J planetocentric distance. We find the 1 keV core protons are likely the seed population for the higher-energy dispersive conics, which are accelerated from a distance of ∼3-5 R_J. Transient wave-particle heating in a "pressure-cooker" process is likely responsible for this proton acceleration. The plasma characteristics and composition during this period show Jupiter's polar-most field lines can be topologically closed, with conjugate magnetic footpoints connected to both hemispheres. Finally, these observations demonstrate energetic protons can be accelerated into Jupiter's magnetotail via wave-particle coupling.