Multivariate geothermal heat flow models of Antarctica, towards Aq2

Heat generated in the interior of the Earth provides an indication of tectonic history and lithospheric architecture. In the case of the Antarctic continent, it has an additional importance, as even moderate amounts of geothermal heat transfer impact the thermo-mechanic properties of the ice sheets....

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Bibliographic Details
Main Authors: Staal, T, Reading, AM, Fox, J, Halpin, JA, Kelly, I, Phipps, SJ, Turner, RJ, Whittaker, JM
Format: Conference Object
Language:English
Published: American Geophysical Union 2020
Subjects:
Engineering
Fluid mechanics and thermal engineering
Computational methods in fluid flow
heat and mass transfer (incl. computational fluid dynamics)
Antarctic
The Antarctic
East Antarctica
Dronning Maud Land
Shackleton
South Pole
Shackleton Range
Gamburtsev Subglacial Mountains
Queen Mary Land
Antarc*
Antarctica
Queen Mary land
South pole
Online Access:http://ecite.utas.edu.au/143106
id ftunivtasecite:oai:ecite.utas.edu.au:143106
record_format openpolar
spelling ftunivtasecite:oai:ecite.utas.edu.au:143106 2023-05-15T13:59:46+02:00 Multivariate geothermal heat flow models of Antarctica, towards Aq2 Staal, T Reading, AM Fox, J Halpin, JA Kelly, I Phipps, SJ Turner, RJ Whittaker, JM 2020 http://ecite.utas.edu.au/143106 en eng American Geophysical Union Staal, T and Reading, AM and Fox, J and Halpin, JA and Kelly, I and Phipps, SJ and Turner, RJ and Whittaker, JM, Multivariate geothermal heat flow models of Antarctica, towards Aq2, American Geophysical Union Fall Meeting 2020, 7-11 December, Virtual Conference, Online (USA) (2020) [Conference Extract] http://ecite.utas.edu.au/143106 Engineering Fluid mechanics and thermal engineering Computational methods in fluid flow heat and mass transfer (incl. computational fluid dynamics) Conference Extract NonPeerReviewed 2020 ftunivtasecite 2021-04-05T22:16:32Z Heat generated in the interior of the Earth provides an indication of tectonic history and lithospheric architecture. In the case of the Antarctic continent, it has an additional importance, as even moderate amounts of geothermal heat transfer impact the thermo-mechanic properties of the ice sheets. In some locations, such geothermal heat is expected to cause basal melting. There are few direct measurements of heat in Antarctica, and due to the large variability, interpolation cannot resolve the spatial distribution. Constraining heat from a temperature gradient derived from univariate geophysical datasets produces contradicting results and depends on unconstrained assumptions. As expected, given the limited data available, the understanding of the thermal properties of Antarctica is far less evolved than for any other continent. We present the multivariate geothermal heat flow model, Aq1, generated from a similarity detection approach of 17 Antarctic observables, and draft the sequential model Aq2, with further improved robustness and uncertainty metrics. Aq1 provides new details in East Antarctica. Low heat flow values around 40mW/m2 are suggested in Wilks Subglacial Basin, Shackleton Range and coastal Dronning Maud Land. The model also suggests elevated heat flow over 70mW/m2 around Gamburtsev Subglacial Mountains, in Queen Mary Land and near the South Pole. However, those suggestions are associated with large uncertainty ranges. Aq2 provides an opportunity to constrain the ambiguities and further improve the robustness. We refine the model parameters by optimizing information entropy and cross-correlated misfit. Aq2 takes advantage of latest seismic tomography models, geological observations and multivariate segmentation. Including higher-resolution tomography improves the spatial resolution of the model result, especially in coastal regions. By comparing Aq2 with calculated maps of steady-state heat flow and other models, we also provide an estimate of the contributing mechanisms that cause excess geothermal heat. We infer the most likely additions from crustal heat production, exhumation, neotectonics and heat transfer from the mantle. Our computational framework is available as an open source resource for the benefit of the solid-Earth and interdisciplinary research communities. Conference Object Antarc* Antarctic Antarctica Dronning Maud Land East Antarctica Queen Mary land South pole South pole eCite UTAS (University of Tasmania) Antarctic The Antarctic East Antarctica Dronning Maud Land Shackleton South Pole Shackleton Range ENVELOPE(-26.000,-26.000,-80.833,-80.833) Gamburtsev Subglacial Mountains ENVELOPE(76.000,76.000,-80.500,-80.500) Queen Mary Land ENVELOPE(96.000,96.000,-68.000,-68.000)
institution Open Polar
collection eCite UTAS (University of Tasmania)
op_collection_id ftunivtasecite
language English
topic Engineering
Fluid mechanics and thermal engineering
Computational methods in fluid flow
heat and mass transfer (incl. computational fluid dynamics)
spellingShingle Engineering
Fluid mechanics and thermal engineering
Computational methods in fluid flow
heat and mass transfer (incl. computational fluid dynamics)
Staal, T
Reading, AM
Fox, J
Halpin, JA
Kelly, I
Phipps, SJ
Turner, RJ
Whittaker, JM
Multivariate geothermal heat flow models of Antarctica, towards Aq2
topic_facet Engineering
Fluid mechanics and thermal engineering
Computational methods in fluid flow
heat and mass transfer (incl. computational fluid dynamics)
description Heat generated in the interior of the Earth provides an indication of tectonic history and lithospheric architecture. In the case of the Antarctic continent, it has an additional importance, as even moderate amounts of geothermal heat transfer impact the thermo-mechanic properties of the ice sheets. In some locations, such geothermal heat is expected to cause basal melting. There are few direct measurements of heat in Antarctica, and due to the large variability, interpolation cannot resolve the spatial distribution. Constraining heat from a temperature gradient derived from univariate geophysical datasets produces contradicting results and depends on unconstrained assumptions. As expected, given the limited data available, the understanding of the thermal properties of Antarctica is far less evolved than for any other continent. We present the multivariate geothermal heat flow model, Aq1, generated from a similarity detection approach of 17 Antarctic observables, and draft the sequential model Aq2, with further improved robustness and uncertainty metrics. Aq1 provides new details in East Antarctica. Low heat flow values around 40mW/m2 are suggested in Wilks Subglacial Basin, Shackleton Range and coastal Dronning Maud Land. The model also suggests elevated heat flow over 70mW/m2 around Gamburtsev Subglacial Mountains, in Queen Mary Land and near the South Pole. However, those suggestions are associated with large uncertainty ranges. Aq2 provides an opportunity to constrain the ambiguities and further improve the robustness. We refine the model parameters by optimizing information entropy and cross-correlated misfit. Aq2 takes advantage of latest seismic tomography models, geological observations and multivariate segmentation. Including higher-resolution tomography improves the spatial resolution of the model result, especially in coastal regions. By comparing Aq2 with calculated maps of steady-state heat flow and other models, we also provide an estimate of the contributing mechanisms that cause excess geothermal heat. We infer the most likely additions from crustal heat production, exhumation, neotectonics and heat transfer from the mantle. Our computational framework is available as an open source resource for the benefit of the solid-Earth and interdisciplinary research communities.
format Conference Object
author Staal, T
Reading, AM
Fox, J
Halpin, JA
Kelly, I
Phipps, SJ
Turner, RJ
Whittaker, JM
author_facet Staal, T
Reading, AM
Fox, J
Halpin, JA
Kelly, I
Phipps, SJ
Turner, RJ
Whittaker, JM
author_sort Staal, T
title Multivariate geothermal heat flow models of Antarctica, towards Aq2
title_short Multivariate geothermal heat flow models of Antarctica, towards Aq2
title_full Multivariate geothermal heat flow models of Antarctica, towards Aq2
title_fullStr Multivariate geothermal heat flow models of Antarctica, towards Aq2
title_full_unstemmed Multivariate geothermal heat flow models of Antarctica, towards Aq2
title_sort multivariate geothermal heat flow models of antarctica, towards aq2
publisher American Geophysical Union
publishDate 2020
url http://ecite.utas.edu.au/143106
long_lat ENVELOPE(-26.000,-26.000,-80.833,-80.833)
ENVELOPE(76.000,76.000,-80.500,-80.500)
ENVELOPE(96.000,96.000,-68.000,-68.000)
geographic Antarctic
The Antarctic
East Antarctica
Dronning Maud Land
Shackleton
South Pole
Shackleton Range
Gamburtsev Subglacial Mountains
Queen Mary Land
geographic_facet Antarctic
The Antarctic
East Antarctica
Dronning Maud Land
Shackleton
South Pole
Shackleton Range
Gamburtsev Subglacial Mountains
Queen Mary Land
genre Antarc*
Antarctic
Antarctica
Dronning Maud Land
East Antarctica
Queen Mary land
South pole
South pole
genre_facet Antarc*
Antarctic
Antarctica
Dronning Maud Land
East Antarctica
Queen Mary land
South pole
South pole
op_relation Staal, T and Reading, AM and Fox, J and Halpin, JA and Kelly, I and Phipps, SJ and Turner, RJ and Whittaker, JM, Multivariate geothermal heat flow models of Antarctica, towards Aq2, American Geophysical Union Fall Meeting 2020, 7-11 December, Virtual Conference, Online (USA) (2020) [Conference Extract]
http://ecite.utas.edu.au/143106
_version_ 1766268551311654912

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