McMurdo Dry Valleys, Antarctica. β NASA
The search for life in the solar system often focuses on water and on environments where habitable conditions exist, persistently or occasionally.
In this search, dry permafrost (ice-free frozen soil) has received minimal attention. It was previously proposed that within martian dry permafrost the water activity ( ππ€, an essential property for habitability) could be enhanced by diurnal thermal cycles and water desorption from soil grains, but the details remain unexplored.
We examined ππ€ in dry soil (which contained only vapor and adsorbed water) through experiments and numerical simulations and contrasted the results with a habitability threshold for terrestrial organisms ( ππ€ββ>ββ0.6). We found that heating cycles in a soil raised ππ€.
As water vapor desorbs from warming soil grains, it diffuses toward cooler adjacent soil, where a fraction of this incoming vapor enhances the local ππ€. In laboratory tests with loess and clay soils, we observed ππ€ to increase by 0.06β0.12. Extrapolating from laboratory to permafrost conditions by using numerical simulations, we found that some Antarctic soils can be boosted periodically into a habitable range.
In contrast, the current martian climate is too dry or cold for this ππ€-enhancement process to impact habitability. However, high-obliquity periods on Mars are analogous to the Antarctic case.
Humidity Enhancement in Dry Permafrost: The Effects of Temperature Cycles on Habitability
Astrobiology via PubMed
#Humidity #Enhancement #Dry #Permafrost #Effects #Temperature #Cycles #Habitability
