Mapping the Brightness of Ganymede's Ultraviolet Aurora using Hubble Space Telescope Observations

TL;DR

This study creates a detailed brightness map of Ganymede's ultraviolet aurora using Hubble data, revealing strong longitudinal and hemispherical variations that inform understanding of its magnetospheric processes.

Contribution

It provides the first high-resolution, long-term brightness map of Ganymede's aurora, highlighting structured crescent patterns and asymmetries in the auroral ovals.

Findings

Auroral brightness varies significantly with longitude.

Northern and southern ovals show different brightness patterns.

Auroral crescents are prominent on leading and trailing sides.

Abstract

We analyze Hubble Space Telescope (HST) observations of Ganymede made with the Space Telescope Imaging Spectrograph (STIS) between 1998 and 2017 to generate a brightness map of Ganymede's oxygen emission at 1356 A. Our Mercator projected map demonstrates that the brightness along Ganymede's northern and southern auroral ovals strongly varies with longitude. To quantify this variation around Ganymede, we investigate the brightness averaged over 36$^{\circ}$-wide longitude corridors centered around the sub-Jovian (0$^{\circ}$ W), leading (90$^{\circ}$ W), anti-Jovian (180$^{\circ}$ W), and trailing (270$^{\circ}$ W) central longitudes. In the northern hemisphere, the brightness of the auroral oval is 3.7 $\pm$ 0.4 times lower in the sub-Jovian and anti-Jovian corridors compared to the trailing and leading corridors. The southern oval is overall brighter than the northern oval, and only 2.5 $\pm$ 0.2 times fainter on the sub- and anti-Jovian corridors compared to the trailing and leading corridors. This demonstrates that Ganymede's auroral ovals are strongly structured in auroral crescents on the leading side (plasma downstream side) and on the trailing side (plasma upstream side). We also find that the brightness is not symmetric with respect to the 270$^\circ$ meridian, but shifted by $\sim$20$^\circ$ towards the Jovian-facing hemisphere. Our map will be useful for subsequent studies to understand the processes that generate the aurora in Ganymede's non-rotationally driven, sub-Alfv\'{e}nic magnetosphere.