The Planetary Science Journal (Jan 2022)

A CO2 Cycle on Ariel? Radiolytic Production and Migration to Low-latitude Cold Traps

  • Richard J. Cartwright,
  • Tom A. Nordheim,
  • Riley A. DeColibus,
  • William M. Grundy,
  • Bryan J. Holler,
  • Chloe B. Beddingfield,
  • Michael M. Sori,
  • Michael P. Lucas,
  • Catherine M. Elder,
  • Leonardo H. Regoli,
  • Dale P. Cruikshank,
  • Joshua P. Emery,
  • Erin J. Leonard,
  • Corey J. Cochrane

DOI
https://doi.org/10.3847/PSJ/ac3d30
Journal volume & issue
Vol. 3, no. 1
p. 8

Abstract

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CO _2 ice is present on the trailing hemisphere of Ariel but is mostly absent from its leading hemisphere. The leading/trailing hemispherical asymmetry in the distribution of CO _2 ice is consistent with radiolytic production of CO _2 , formed by charged particle bombardment of H _2 O ice and carbonaceous material in Ariel’s regolith. This longitudinal distribution of CO _2 on Ariel was previously characterized using 13 near-infrared reflectance spectra collected at “low” sub-observer latitudes between 30°S and 30°N. Here we investigated the distribution of CO _2 ice on Ariel using 18 new spectra: 2 collected over low sub-observer latitudes, 5 collected at “mid” sub-observer latitudes (31°N–44°N), and 11 collected over “high” sub-observer latitudes (45°N–51°N). Analysis of these data indicates that CO _2 ice is primarily concentrated on Ariel’s trailing hemisphere. However, CO _2 ice band strengths are diminished in the spectra collected over mid and high sub-observer latitudes. This sub-observer latitudinal trend may result from radiolytic production of CO _2 molecules at high latitudes and subsequent migration of this constituent to low-latitude cold traps. We detected a subtle feature near 2.13 μ m in two spectra collected over high sub-observer latitudes, which might result from a “forbidden” transition mode of CO _2 ice that is substantially stronger in well-mixed substrates composed of CO _2 and H _2 O ice, consistent with regolith-mixed CO _2 ice grains formed by radiolysis. Additionally, we detected a 2.35 μ m feature in some low sub-observer latitude spectra, which might result from CO formed as part of a CO _2 radiolytic production cycle.

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