Distribution of Mid-Latitude Ground Ice on Mars from New Impact Craters

Shane Byrne(University of Arizona), C. M. Dundas(University of Arizona), M. R. Kennedy(Malin Space Science Systems (United States)), M. T. Mellon(University of Colorado Boulder), A. S. McEwen(University of Arizona), Selby Cull(Washington University in St. Louis), I. J. Daubar(University of Arizona), David Shean(Malin Space Science Systems (United States)), K. D. Seelos(Johns Hopkins University Applied Physics Laboratory), S. L. Murchie(Johns Hopkins University Applied Physics Laboratory), B. A. Cantor(Malin Space Science Systems (United States)), R. E. Arvidson(Washington University in St. Louis), K. S. Edgett(Malin Space Science Systems (United States)), A. Reufer(University of Bern), Nicolas Thomas(University of Bern), T. N. Harrison(Malin Space Science Systems (United States)), L. Posiolova(Malin Space Science Systems (United States)), F. P. Seelos(Johns Hopkins University Applied Physics Laboratory)
Science
September 25, 2009
10.1126/science.1175307
Cited by 325

Abstract

New impact craters at five sites in the martian mid-latitudes excavated material from depths of decimeters that has a brightness and color indicative of water ice. Near-infrared spectra of the largest example confirm this composition, and repeated imaging showed fading over several months, as expected for sublimating ice. Thermal models of one site show that millimeters of sublimation occurred during this fading period, indicating clean ice rather than ice in soil pores. Our derived ice-table depths are consistent with models using higher long-term average atmospheric water vapor content than present values. Craters at most of these sites may have excavated completely through this clean ice, probing the ice table to previously unsampled depths of meters and revealing substantial heterogeneity in the vertical distribution of the ice itself.

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