Recent Basal Melting of a Mid-Latitude Glacier on Mars

Evidence for past basal melting of young (late Amazonian-aged), debris-covered glaciers in Mars' mid-latitudes is extremely rare. Thus, it is widely thought that these viscous flow features (VFFs) have been perennially frozen to their beds. We identify an instance of recent, localized wet-based...

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Bibliographic Details
Published in:Journal of Geophysical Research: Planets
Main Authors: Butcher, Frances E G, Balme, Matthew R, Gallagher, Colman, Arnold, Neil S, Conway, Susan J, Hagermann, Axel, Lewis, Stephen R
Other Authors: The Open University, University College Dublin (UCD), University of Cambridge, University of Nantes, Biological and Environmental Sciences, orcid:0000-0002-1818-9396
Format: Article in Journal/Newspaper
Language:English
Published: Wiley-Blackwell 2017
Subjects:
Mars
glacier
esker
meltwater
wet‐based glaciation
geothermal
Mars Glacier
Online Access:http://hdl.handle.net/1893/26992
https://doi.org/10.1002/2017JE005434
http://dspace.stir.ac.uk/bitstream/1893/26992/1/Butcher_et_al-2017-Journal_of_Geophysical_Research_A_Planets.pdf
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Summary:Evidence for past basal melting of young (late Amazonian-aged), debris-covered glaciers in Mars' mid-latitudes is extremely rare. Thus, it is widely thought that these viscous flow features (VFFs) have been perennially frozen to their beds. We identify an instance of recent, localized wet-based mid-latitude glaciation, evidenced by a candidate esker emerging from a VFF in a tectonic rift in Tempe Terra. Eskers are sedimentary ridges deposited in ice-walled meltwater conduits and are indicative of glacial melting. We compare the candidate esker to terrestrial analogues, present a geomorphic map of landforms in the rift, and develop a landsystem model to explain their formation. We propose that the candidate esker formed during a transient phase of wet-based glaciation. We then consider the similarity between the geologic setting of the new candidate esker and that of the only other candidate esker to be identified in association with an existing mid-latitude VFF; both are within tectonic graben/rifts proximal to volcanic provinces. Finally, we calculate potential basal temperatures for a range of VFF thicknesses, driving stresses, mean annual surface temperatures, and geothermal heat fluxes, which unlike previous studies, include the possible role of internal strain heating. Strain heating can form an important additional heat source, especially in flow convergence zones, or where ice is warmer due to elevated surface temperatures or geothermal heat flux. Elevated geothermal heat flux within rifts, perhaps combined with locally-elevated strain heating, may have permitted wet-based glaciation during the late Amazonian, when cold climates precluded more extensive wet-based glaciation on Mars. ©2017. The Authors.

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