Digging Into the Surface of the Icy Dwarf Planet Eris

TL;DR

This study uses optical spectroscopy to analyze Eris's surface, revealing a potential increase in nitrogen ice with depth, and proposes a seasonal sublimation and deposition mechanism explaining surface composition variations.

Contribution

It presents the first spectroscopic evidence of nitrogen ice increasing with depth on Eris and introduces a seasonal sublimation model to explain surface compositional layering.

Findings

Correlation between blue shift and albedo at methane bands

Evidence for nitrogen ice increasing with depth

Proposed seasonal sublimation and deposition mechanism

Abstract

We describe optical spectroscopic observations of the icy dwarf planet Eris with the 6.5 meter MMT telescope and the Red Channel Spectrograph. We report a correlation, that is at the edge of statistical significance, between blue shift and albedo at maximum absorption for five methane ice bands. We interpret the correlation as an increasing dilution of methane ice with another ice component, probably nitrogen, with increasing depth into the surface. We suggest a mechanism to explain the apparent increase in nitrogen with depth. Specifically, if we are seeing Eris 50 degrees from pole-on (Brown and Schaller, 2008), the pole we are seeing now at aphelion was in winter darkness at perihelion. Near perihelion, sublimation could have built up atmospheric pressure on the sunlit (summer) hemisphere sufficient to drive winds toward the dark (winter) hemisphere, where the winds would condense. Because nitrogen is more volatile and scarcer than methane, it sublimated from the sunlit hemisphere relatively early in the season, so the early summer atmosphere was nitrogen rich, and so was the ice deposited on the winter pole. Later in the season, much of the nitrogen was exhausted from the summer pole, but there was plenty of methane, which continued to sublimate. At this point, the atmosphere was more depleted in nitrogen, as was the ice freezing out on top of the earlier deposited nitrogen rich ice.