Io's Optical Aurorae in Jupiter's Shadow

TL;DR

This study investigates Io's optical aurorae response during Jupiter's shadow, revealing distinct behaviors of atomic and molecular emissions and highlighting the dominance of photon-driven processes over electron impact in auroral excitation.

Contribution

First exploration of Io's optical aurorae response to eclipse, demonstrating the roles of ion chemistry and photon impact in auroral brightness variations.

Findings

Oxygen brightness tracks plasma density, unaffected by eclipse.

Na aurora diminishes rapidly during eclipse, recovering slowly.

Potassium emissions confirm K as a major source of red auroral light.

Abstract

Decline and recovery timescales surrounding eclipse are indicative of the controlling physical processes in Io's atmosphere. Recent studies have established that the majority of Io's molecular atmosphere, SO2 and SO, condenses during its passage through Jupiter's shadow. The eclipse response of Io's atomic atmosphere is less certain, having been characterized solely by ultraviolet aurorae. Here we explore the response of optical aurorae for the first time. We find oxygen to be indifferent to the changing illumination, with [O I] brightness merely tracking the plasma density at Io's position in the torus. In shadow, line ratios confirm sparse SO2 coverage relative to O, since their collisions would otherwise quench the emission. Io's sodium aurora mostly disappears in eclipse and e-folding timescales, for decline and recovery differ sharply: ~10 minutes at ingress and nearly 2 hr at egress. Only ion chemistry can produce such a disparity; Io's molecular ionosphere is weaker at egress due to rapid recombination. Interruption of a NaCl+ photochemical pathway best explains Na behavior surrounding eclipse, implying that the role of electron impact ionization is minor relative to photons. Auroral emission is also evident from potassium, confirming K as the major source of far red emissions seen with spacecraft imaging at Jupiter. In all cases, direct electron impact on atomic gas is sufficient to explain the brightness without invoking significant dissociative excitation of molecules. Surprisingly, the nonresponse of O and rapid depletion of Na is opposite the temporal behavior of their SO2 and NaCl parent molecules during Io's eclipse phase.