Photochemical depletion of heavy CO isotopes in the Martian atmosphere
Nature Astronomy Springer Nature 7:7 (2023) 867-876
Abstract:
The atmosphere of Mars is enriched in heavy isotopes with respect to Earth as a result of the escape of the atmosphere to space over billions of years. Estimating this enrichment requires a rigorous understanding of all atmospheric processes that contribute to the evolution of isotopic ratios between the lower and upper atmosphere, where escape processes take place. We combine measurements of CO vertical profiles obtained by the Atmospheric Chemistry Suite on board the ExoMars Trace Gas Orbiter with the predictions of a photochemical model and find evidence of a process of photochemistry-induced fractionation that depletes the heavy isotopes of C and O in CO (δ13C = −160 ± 90‰ and δ18O = −20 ± 110‰). In the upper atmosphere, accounting for this process reduces the escape fractionation factor by ~25%, suggesting that less C has escaped from the atmosphere of Mars than previously thought. In the lower atmosphere, incorporation of this 13C-depleted CO fractionation into the surface could support the abiotic origin of recently found Martian organics.Effects of Albedo on the MIR Emissivity Spectra of Silicates for Lunar Comparison
Journal of Geophysical Research Planets American Geophysical Union (AGU) 128:4 (2023)
Short Period Seismometer for the Lunar Farside Seismic Suite Mission
Institute of Electrical and Electronics Engineers (IEEE) 00 (2023) 1-9
Quantification of carbonates, oxychlorines, and chlorine generated by heterogeneous electrochemistry induced by Martian dust activity
Geophysical Research Letters American Geophysical Union 50:4 (2023) e2022GL102127
Abstract:
Heterogeneous electrochemistry induced by Martian dust activity is an important type of atmosphere-surface interaction that affects geochemical processes at the Martian surface and in the Martian atmosphere. We have experimentally demonstrated that heterogeneous electrochemistry stimulated by mid-strength dust events can decompose common chloride salts, which is accompanied by the release of chlorine atoms into the atmosphere and the generation of (per)chlorates (chlorates and perchlorates) and carbonates. In this study, we present quantitative analyses on the above products from 26 heterogeneous electrochemical experiments on chloride salts. Based on these quantifications, our calculation indicates that such atmosphere-surface interaction during a portion of Amazonian period could accumulate the observed abundance of (per)chlorates, carbonates, and HCl by landed and orbital missions, and thus can be considered as a major driving force of the global chlorine-cycle on Mars. This study emphasizes the importance of measuring the electrical properties of dust activity on Mars.Origin and Evolution of Enceladus's Tidal Dissipation.
Space science reviews 219:7 (2023) 57