Ozone production in electron irradiated CO2:O2 ices

Duncan V. Mifsud, Zuzana Kaňuchová, Sergio Ioppolo, Péter Herczku, Alejandra Traspas Muiña, Béla Sulik, K. K. Rahul, Sándor T. S. Kovács, Perry A. Hailey, Robert W. McCullough, Nigel J. Mason, Zoltán Juhász

Research output: Contribution to journalArticlepeer-review

6 Citations (Scopus)
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Abstract

The detection of ozone (O3) in the surface ices of Ganymede, Jupiter's largest moon, and of the Saturnian moons Rhea and Dione, has motivated several studies on the route of formation of this species. Previous studies have successfully quantified trends in the production of O3 as a result of the irradiation of pure molecular ices using ultraviolet photons and charged particles (i.e., ions and electrons), such as the abundances of O3 formed after irradiation at different temperatures or using different charged particles. In this study, we extend such results by quantifying the abundance of O3 as a result of the 1 keV electron irradiation of a series of 14 stoichiometrically distinct CO2:O2 astrophysical ice analogues at 20 K. By using mid-infrared spectroscopy as our primary analytical tool, we have also been able to perform a spectral analysis of the asymmetric stretching mode of solid O3 and the variation in its observed shape and profile among the investigated ice mixtures. Our results are important in the context of better understanding the surface composition and chemistry of icy outer Solar System objects, and may thus be of use to future interplanetary space missions such as the ESA Jupiter Icy Moons Explorer and the NASA Europa Clipper missions, as well as the recently launched NASA James Webb Space Telescope.
Original languageEnglish
Pages (from-to) 18169-18178
Number of pages10
Journal Physical Chemistry Chemical Physics
Volume24
Issue number30
Early online date21 Jul 2022
DOIs
Publication statusPublished - 14 Aug 2022

Keywords

  • Physical and Theoretical Chemistry
  • General Physics and Astronomy

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