1. The origin of enhanced O2+ production from photoionized CO2 clusters.
- Author
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Ganguly, Smita, Barreiro-Lage, Dario, Walsh, Noelle, Oostenrijk, Bart, Sorensen, Stacey L., Díaz-Tendero, Sergio, and Gisselbrecht, Mathieu
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MARTIAN atmosphere , *QUANTUM chemistry , *PLANETARY atmospheres , *EXOTHERMIC reactions , *SOFT X rays - Abstract
CO2-rich planetary atmospheres are continuously exposed to ionising radiation driving major photochemical processes. In the Martian atmosphere, CO2 clusters are predicted to exist at high altitudes motivating a deeper understanding of their photochemistry. In this joint experimental-theoretical study, we investigate the photoreactions of CO2 clusters (≤2 nm) induced by soft X-ray ionisation. We observe dramatically enhanced production of O 2 + from photoionized CO2 clusters compared to the case of the isolated molecule and identify two relevant reactions. Using quantum chemistry calculations and multi-coincidence mass spectrometry, we pinpoint the origin of this enhancement: A size-dependent structural transition of the clusters from a covalently bonded arrangement to a weakly bonded polyhedral geometry that activates an exothermic reaction producing O 2 + . Our results unambiguously demonstrate that the photochemistry of small clusters/particles will likely have a strong influence on the ion balance in atmospheres. In the Martian atmosphere, CO2 clusters are predicted to exist at high altitudes motivating a deeper understanding of their photochemistry. Here the authors use quantum chemistry calculations and multi-coincidence mass spectrometry to show that a size-dependent structural transition enhances the production of O 2 + from photoionized CO2 clusters. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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