Your search keyword '"Prieto-Ballesteros, Olga"' showing total 2 results

1. Martian hydrogeology sustained by thermally insulating gas and salt hydrates

Author

Kargel, Jeffrey S., Furfaro, Roberto, Prieto-Ballesteros, Olga, Rodriguez, J. Alexis P., Montgomery, David R., Gillespie, Alan R., Marion, Giles M., and Wood, Stephen E.

Subjects

Mars (Planet) -- Natural history, Hydrates -- Properties, Hydrogeology -- Research, Numerical analysis -- Usage, Earth sciences

Abstract

Numerical simulations and geologic studies suggest that high thermal anomalies beneath, within, and above thermally insulating layers of buried hydrated salts and gas hydrates could have triggered and sustained hydrologic processes on Mars, producing or modifying chaotic terrains, debris flows, gullies, and ice-creep features. These simulations and geologic examples suggest that thick hydrate deposits may sustain such geothermal anomalies, shallow groundwater tables, and hydrogeologic activity for eons. The proposed mechanism may operate and be self-reinforcing even in today's cold Martian climate without elevated heat flux. Keywords: Mars, heat flow, hydrous sulfates, clathrate hydrates, Aram Chaos. doi: 10.1130/G23783A.1

Published

2007

2. Interglacial clathrate destabilization on Mars: possible contributing source of its atmospheric methane

Author

Prieto-Ballesteros, Olga, Kargel, Jeffrey S., Fairen, Alberto G., Fernandez-Remolar, David C., Dohm, James M., and Amils, Ricardo

Subjects

Methane -- Environmental aspects, Mars (Planet) -- Environmental aspects, Mars (Planet) -- Atmosphere, Mars (Planet) -- Composition, Earth sciences

Abstract

The presence of methane has been recently detected in the martian atmosphere, suggesting a contemporary source such as volcanism or microbial activity. Here we show that methane may be released by the destabilization of methane clathrate hydrates, triggered by the interglacial climate change starting 0.4 Ma. Clathrate hydrates are nonstoichiometric crystalline compounds in which a water ice lattice forms cages that contain apolar gas molecules, such as methane [C[H.sub.4]*n[H.sub.2]O] and carbon dioxide [C[O.sub.2]*n[H.sub.2]O]. The loss of shallow ground ice eliminates confining pressure, initiating the destabilization of clathrate hydrates and the release of methane to the atmosphere. This alternative process does not restrict the methane's age to 430 yr (maximum residence time of methane gas in martian atmosphere), because clathrate hydrates can preserve (encage) methane of ancient origin for long time periods. Keywords: methane, Mars, clathrate, hydrate.

Published

2006