On the origin of molecular oxygen on the surface of Ganymede

TL;DR

This study combines ground-based spectroscopy and laboratory experiments to investigate the presence and state of molecular oxygen ice on Ganymede's surface, suggesting it exists in mixed ices at low temperatures.

Contribution

It provides new observational and experimental evidence supporting the existence of O2 ice in mixed ices on Ganymede, clarifying its spectral features and temperature conditions.

Findings

O2 ice bands are confirmed in Ganymede's spectra.

Mixed ices with H2O and CO2 better match observations than pure O2.

O2 can be trapped in ices at higher temperatures than previously thought.

Abstract

Since its first identification on the surface of Ganymede in 1995, molecular oxygen (O2) ice has been at the center of a scientific debate as the surface temperature of the Jovian moon is on average well above the freezing point of O2. Laboratory evidence suggested that solid O2 may either exist in a cold (<50 K) subsurface layer of the icy surface of Ganymede, or it is in an atmospheric haze of the moon. Alternatively, O2 is constantly replenished at the surface through ion irradiation of water-containing ices. A conclusive answer on the existence of solid O2 on the surface of Ganymede is hampered by the lack of detailed, extensive observational datasets. We present new ground-based, high-resolution spectroscopic observations of Ganymede's surface obtained at the Telescopio Nazionale Galileo. These are combined with dedicated laboratory measurements of ultraviolet-visible (UV-vis) photoabsorption spectra of O2 ice, both pure and mixed with other species of potential interest for the Galilean satellites. Our study confirms that the two bands identified in the visible spectra of Ganymede's surface are due to the (1,0) and (0,0) transition bands of O2 ice. Oxygen-rich ice mixtures including water (H2O) and carbon dioxide (CO2) can reproduce observational reflectance data of the Ganymede's surface better than pure O2 ice in the temperature range 20-35 K. Solid H2O and CO2 also provide an environment where O2 ice can be trapped at higher temperatures than its pure ice desorption under vacuum space conditions. Our experiments at different temperatures show also that the (1,0)/(0,0) ratio in case of the CO2:O2=1:2 ice mixture at 35 K has the closest value to observations, while at 30 K the (1,0)/(0,0) ratio seems to be mixture independent with the exception of the N2:O2=1:2 ice mixture. The present work will support the ESA/JUICE mission to the Jovian system.