New geological insights fingerprint high heat producing crust in the remote interior of Wilkes Land, East Antarctica

Heat produced by radioactive decay within East Antarctic crust provides a significant contribution to the total heat flow balance that is supplied at the base of the East Antarctic Ice Sheet. However, the distribution of heat-producing crustal rocks in ice-covered regions remains poorly constrained....

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Bibliographic Details
Main Authors: Maritati, A, Halpin, J, Whittaker, J
Format: Conference Object
Language:English
Published: . 2018
Subjects:
Earth Sciences
Geology
Geochronology
Antarctic
East Antarctica
East Antarctic Ice Sheet
Wilkes Land
Windmill Islands
Totten Glacier
Antarc*
Antarctica
Ice Sheet
Online Access:https://www.conferences.com.au/2018-taking-the-temperature-of-the-antarctic-continent-new/
http://ecite.utas.edu.au/131197
Description
Summary:Heat produced by radioactive decay within East Antarctic crust provides a significant contribution to the total heat flow balance that is supplied at the base of the East Antarctic Ice Sheet. However, the distribution of heat-producing crustal rocks in ice-covered regions remains poorly constrained. Wilkes Land, East Antarctica hosts the Totten Glacier catchment area, one of the largest ice drainage basins in East Antarctica, and is one region where an improved knowledge of sub-glacial geology is of fundamental importance to understanding solid Earth-cryosphere interactions. We examined the provenance of three low-grade quartzite erratic samples from the Windmill Islands region to provide evidence of the age and composition of the ice-covered bedrock. We suggest these quartzite erratic samples were sourced from a previously-unknown intra-continental sedimentary basin in the interior of Wilkes Land. UPb ages of detrital zircons include dominant age peaks at c. 1200 Ma and c. 1490 Ma, which fingerprint the provenance of this sedimentary basin. Based on the detrital zircon record in these quartzite erratic samples, and using recent Australia-Antarctica plate reconstructions, we suggest there are heat-producing granitic source rocks in Wilkes Land equivalent in age and composition to those present in the Coompana Province of southwestern Australia. We further suggest that the significant heat production variability that characterises the Coompana granitic basement (2.526.39 μW/m 3 ) can therefore also be expected in the interior of Wilkes Land. These new geological insights indicate that a higher and more variable regional sub-glacial heat flow might be expected in this region than currently resolved in available models.

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