Affiliation:
1. Department of Environmental Sciences University of Virginia Charlottesville VA USA
2. School of Computing and Augmented Intelligence Arizona State University Tempe AZ USA
3. Department of Civil, Architectural, and Environmental Engineering Center for Water and the Environment University of Texas at Austin Austin TX USA
4. School of Earth and Space Exploration Arizona State University Tempe AZ USA
5. Planetary Science Institute Tucson AZ USA
Abstract
AbstractFan‐shaped sedimentary deposits are key indicators of paleoclimate on Mars. The largest example, a multi‐lobed deposit (>1,000 km2) at the outlet of Hypanis Valles, may have formed either subaerially or at the edge of a water body. We used a numerical model to test whether these contrasting basin boundary conditions would cause deposit geometries that are diagnostic and distinguishable from orbit. We compared depositional scenarios with either (a) fully subaerial conditions, (b) a constant water level, or (c) a falling water level. In the model, standing water generates deposits that are thicker, less extensive, and increase in dip angle from proximal to distal locations. Nonetheless, deposit geometries for all scenarios are consistent with orbital observations, which are inconclusive regarding a topset‐foreset break that would indicate standing water. Thus, it is possible that the Hypanis deposits formed subaerially, without a water body onlapping the Mars dichotomy boundary.
Funder
Virginia Space Grant Consortium
Publisher
American Geophysical Union (AGU)
Subject
General Earth and Planetary Sciences,Geophysics