Physics – Geophysics
Scientific paper
Apr 2003
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2003jgre..108.8036d&link_type=abstract
Journal of Geophysical Research (Planets), Volume 108, Issue E4, pp. GDS 17-1, CiteID 8036, DOI 10.1029/2002JE001888
Physics
Geophysics
9
Planetology: Solar System Objects: Mars, Planetology: Solar System Objects: Comparative Planetology, Planetary Sciences: Surface Materials And Properties, Exploration Geophysics: Magnetic And Electrical Methods
Scientific paper
The discovery of rock glacier-like features on Mars suggests the presence of flowing, or once-flowing, ice-rock mixtures. These landforms, which include lobate debris aprons, concentric crater fill, and lineated valley fill, hold significant promise as reservoirs of stored water ice that could be used as fuel sources for human exploration of Mars and provide a frozen record of the climatic history of the planet. To understand the deformation and distribution of ice within these landforms, fundamental descriptions of their internal structure and development are required. To this end, a ground-penetrating radar investigation was initiated using rock glaciers in the San Juan Mountains of Colorado as surrogates for similar Martian landforms. Results obtained from one of these rock glaciers show that the interior of the landform is composed of a layered permafrost matrix of ice, sediment, and ice lenses that comprise thicker depositional units formed through high-magnitude debris falls. Folds in the uppermost layers correspond to the surface expression of ridges and furrows, suggesting that compressive stresses originating in the accumulation zone are transmitted downslope through the rock glacier. Rock glacier features on Mars may also consist of layered permafrost, which would suggest a history of development involving seasonal frost accumulation and/or water influx from below. In terms of water storage within Martian analogs, consideration must include the possibility that some water ice may be stored in relatively pure form within lenses and vein networks such as observed in the surrogate rock glacier of this study.
Degenhardt J. Jr. J.
Giardino John R.
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