Water-Ice Dominated Spectra of Saturn's Rings and Small Moons from JWST

TL;DR

JWST's infrared spectra of Saturn's rings and moons reveal dominant crystalline water ice features, variable ice compositions, and potential organic signatures, providing new insights into their surface compositions and aiding future outer solar system studies.

Contribution

First detailed infrared spectral analysis of Saturn's rings and moons using JWST, highlighting water ice properties and compositional variations with unprecedented clarity.

Findings

Rings and moons spectra dominated by crystalline water ice.

Detection of deuterated water-ice absorption at 4.13 microns.

Spectral features suggest variable ice mixtures and possible organic compounds.

Abstract

JWST measured the infrared spectra of Saturn's rings and several of its small moons (Epimetheus, Pandora, Telesto and Pallene) as part of Guaranteed Time Observation program 1247. The NIRSpec instrument obtained near-infrared spectra of the small moons between 0.6 and 5.3 microns, which are all dominated by water-ice absorption bands. The shapes of the water-ice bands for these moons suggests that their surfaces contain variable mixes of crystalline and amorphous ice or variable amounts of contaminants and/or sub-micron ice grains. The near-infrared spectrum of Saturn's A ring has exceptionally high signal-to-noise between 2.7 and 5 microns and is dominated by features due to highly crystalline water ice. The ring spectrum also confirms that the rings possess a 2-3% deep absorption at 4.13 microns due to deuterated water-ice previously seen by the Visual and Infrared Mapping Spectrometer onboard the Cassini spacecraft. This spectrum also constrains the fundamental absorption bands of carbon dioxide and carbon monoxide and may contain evidence for a weak aliphatic hydrocarbon band. Meanwhile, the MIRI instrument obtained mid-infrared spectra of the rings between 4.9 and 27.9 microns, where the observed signal is a combination of reflected sunlight and thermal emission. This region shows a strong reflectance peak centered around 9.3 microns that can be attributed to crystalline water ice. Since both the near and mid-infrared spectra are dominated by highly crystalline water ice, they should provide a useful baseline for interpreting the spectra of other objects in the outer solar system with more complex compositions.