Stability of mid-latitude snowpacks on Mars

Christensen [2003. Nature 422, 45–48] suggested that runoff from melting snowpacks on martian slopes might be responsible for carving gullies. He also suggested that snowpacks currently exist on Mars, for example on the walls of Dao Valles (approximately 33° S). Such snowpacks were presumably formed...

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Published inIcarus (New York, N.Y. 1962) Vol. 196; no. 2; pp. 565 - 577
Main Authors Williams, K.E., Toon, O.B., Heldmann, J.L., McKay, C., Mellon, M.T.
Format Journal Article
LanguageEnglish
Published San Diego, CA Elsevier Inc 01.08.2008
Elsevier
Subjects
Astronomy
Earth, ocean, space
Exact sciences and technology
Ices
Mars
Solar system
surface
Mars
Ices
Ices,Mars
Albedo
surface
Ice
Models
Solar system
Obliqueness
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Summary:Christensen [2003. Nature 422, 45–48] suggested that runoff from melting snowpacks on martian slopes might be responsible for carving gullies. He also suggested that snowpacks currently exist on Mars, for example on the walls of Dao Valles (approximately 33° S). Such snowpacks were presumably formed during the last obliquity cycle, which occurred about 70,000 years ago. In this paper we investigate a specific scenario under conditions we believe are favorable for snowpack melting. We model the rate at which a snowpack located at 33° S on a poleward-facing slope sublimates and melts on Mars, as well as the temperature profile within the snowpack. Our model includes the energy and mass balance of a snowpack experiencing diurnal variations in insolation. Our results indicate that a dirty snowpack would quickly sublimate and melt under current martian climate conditions. For example a 1 m thick dusty snowpack of moderate density (550 kg/m 3) and albedo (0.39) would sublimate in less than two seasons, producing a small amount of meltwater runoff. Similarly, a cleaner snowpack (albedo 0.53) would disappear in less than 9 seasons. These results suggest that the putative snowpack almost certainly could not have survived for 70,000 years. For most of the parameter settings snowpack interior temperatures at this latitude and slope do reach the melting point. Under most conditions melting occurs when the snowpack is less than 10 cm thick. The modeled snowpack will not melt if it is covered by a 1 cm dust lag. In general, these findings raise interesting possibilities regarding gully formation, but perhaps mostly during a past climate regime when snowfall was expected to have occurred. If there currently are exposed snowpacks on martian mid-latitude slopes, then these ice sheets cannot last long. Hence they might be time variable features on Mars and should be searched for.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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ISSN:0019-1035
1090-2643
DOI:10.1016/j.icarus.2008.03.017