Biology
Scientific paper
Mar 1989
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1989exmm.nasa...26g&link_type=abstract
In NASA, Ames Research Center, Exobiology and Future Mars Missions p 26 (SEE N89-26334 20-51)
Biology
2
Air Water Interactions, Erosion, Lakes, Mars Surface, Planetary Evolution, Planetary Geology, Playas, Landforms, Mars Craters, Morphology, Valleys
Scientific paper
The valley systems in Mars' ancient cratered terrain provide strong evidence for a warmer and wetter climate very early in planetary history. The valley systems in some instances debouch into closed depressions that could have acted as local ponding basins for the flow. A survey of the Martian equatorial region shows that numerous local depressions at the confluence of valley systems exist. These depressions (approximately 100 km) typically are characterized by many valleys flowing into them and few or none flowing out. If ponding did take place, these basin would have contained lakes for some period during Mars' early warmer epoch. Although the collection basins are numerous, location of ones that have not suffered significant subsequent geologic modification is difficult. Some morphologic features suggest that volcanic lavas may have filled them subsequent to any early fluvial activity. Two detailed maps of valley systems and local ponding basins in USGC 1:2,000,000 subquadrangles were completed and a third is in progress. The completed regions are in Mare Tyrrhenum (MC-22 SW) and Margarifter Sinus (MC-19 SE), and the region in progress is in Iapygia (MC-21 NW). On the maps, the valley systems and interpreted margins of ponding basins are indicated. The depressions are of interest for two reasons. First, the depressions were surely the sites in which the materials eroded from the valleys were deposited. Such sediments could preserve important information about the physical conditions at the time of deposition. Second, the sediments could preserve evidence of water-atmosphere interactions during the early period of the Martian climate. Atmospheric carbon dioxide would dissolve in water, and solid carbonate minerals would tend to precipitate out to form carbonate sedimentary deposits. Formation of carbonates in this manner might account for some of the CO2 lost from the early more dense atmosphere.
Goldspiel Jules M.
Squyres Steve W.
No associations
LandOfFree
Ancient lakes on Mars? does not yet have a rating. At this time, there are no reviews or comments for this scientific paper.
If you have personal experience with Ancient lakes on Mars?, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Ancient lakes on Mars? will most certainly appreciate the feedback.
Profile ID: LFWR-SCP-O-1803357