Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach

We present a machine learning approach to statistically derive geothermal heat flow (GHF) for Antarctica. The adopted approach estimates GHF from multiple geophysical and geological data sets, assuming that GHF is substantially related to the geodynamic setting of the plates. We apply a Gradient Boo...

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Bibliographic Details
Main Authors: Lösing, M., Ebbing, J.
Format: Text
Language:English
Published: FID GEO 2021
Subjects:
Antarctic
East Antarctica
Antarc*
Antarctica
Ice Sheet
Online Access:https://dx.doi.org/10.23689/fidgeo-5172
https://e-docs.geo-leo.de/handle/11858/9518
id ftdatacite:10.23689/fidgeo-5172
record_format openpolar
spelling ftdatacite:10.23689/fidgeo-5172 2023-05-15T13:30:55+02:00 Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach Lösing, M. Ebbing, J. 2021 https://dx.doi.org/10.23689/fidgeo-5172 https://e-docs.geo-leo.de/handle/11858/9518 en eng FID GEO Article article-journal Text ScholarlyArticle 2021 ftdatacite https://doi.org/10.23689/fidgeo-5172 2022-02-08T12:34:39Z We present a machine learning approach to statistically derive geothermal heat flow (GHF) for Antarctica. The adopted approach estimates GHF from multiple geophysical and geological data sets, assuming that GHF is substantially related to the geodynamic setting of the plates. We apply a Gradient Boosted Regression Tree algorithm to find an optimal prediction model relating GHF to the observables. The geophysical and geological features are primarily global data sets, which are often unreliable in polar regions due to limited data coverage. Quality and reliability of the data sets are reviewed and discussed in line with the estimated GHF model. Predictions for Australia, where an extensive database of GHF measurements exists, demonstrate the validity of the approach. In Antarctica, only a sparse number of direct GHF measurements are available. Therefore, we explore the use of regional data sets of Antarctica and its tectonic Gondwana neighbors to refine the predictions. With this, we demonstrate the need for adding reliable data to the machine learning approach. Finally, we present a new geothermal heat flow map, which exhibits intermediate values compared to previous models, ranging from 35 to 156 mW/m2, and visible connections to the conjugate margins in Australia, Africa, and India. : Plain Language Summary: The heat energy transferred from the Earth's interior to the surface (geothermal heat flow) can substantially affect the dynamics of an overlying ice sheet. It can lead to melting at the base and hence, decouple the ice sheet from the bedrock. In Antarctica, this parameter is poorly constrained, and only a sparse number of thermal gradient measurements exist. Indirect methods, therefore, try to estimate the continental Antarctic heat flow. Here, we use a machine learning approach to combine multiple information on geology, tectonic setting, and heat flow measurements from all continents to predict Antarctic values. We further show that using reliable data is crucial for the resulting prediction and a mindful choice of features is recommendable. The final result exhibits values within the range of previously proposed heat flow maps and shows local similarities to the continents once connected to East Antarctica within the supercontinent Gondwana. We suggest a minimum and maximum heat flow map, which can be used as input for ice sheet modeling and sea level rise predictions. : Key Points: A new geothermal heat flow map of Antarctica is established by adopting a machine learning approach. Input features include both global and regional geological and tectonic information, and heat flow observations. A Gondwana reconstruction shows connections of heat flow at the conjugate margins of East Antarctica. : Deutsche Forschungsgemeinschaft (DFG) http://dx.doi.org/10.13039/501100001659 Text Antarc* Antarctic Antarctica East Antarctica Ice Sheet DataCite Metadata Store (German National Library of Science and Technology) Antarctic East Antarctica
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
description We present a machine learning approach to statistically derive geothermal heat flow (GHF) for Antarctica. The adopted approach estimates GHF from multiple geophysical and geological data sets, assuming that GHF is substantially related to the geodynamic setting of the plates. We apply a Gradient Boosted Regression Tree algorithm to find an optimal prediction model relating GHF to the observables. The geophysical and geological features are primarily global data sets, which are often unreliable in polar regions due to limited data coverage. Quality and reliability of the data sets are reviewed and discussed in line with the estimated GHF model. Predictions for Australia, where an extensive database of GHF measurements exists, demonstrate the validity of the approach. In Antarctica, only a sparse number of direct GHF measurements are available. Therefore, we explore the use of regional data sets of Antarctica and its tectonic Gondwana neighbors to refine the predictions. With this, we demonstrate the need for adding reliable data to the machine learning approach. Finally, we present a new geothermal heat flow map, which exhibits intermediate values compared to previous models, ranging from 35 to 156 mW/m2, and visible connections to the conjugate margins in Australia, Africa, and India. : Plain Language Summary: The heat energy transferred from the Earth's interior to the surface (geothermal heat flow) can substantially affect the dynamics of an overlying ice sheet. It can lead to melting at the base and hence, decouple the ice sheet from the bedrock. In Antarctica, this parameter is poorly constrained, and only a sparse number of thermal gradient measurements exist. Indirect methods, therefore, try to estimate the continental Antarctic heat flow. Here, we use a machine learning approach to combine multiple information on geology, tectonic setting, and heat flow measurements from all continents to predict Antarctic values. We further show that using reliable data is crucial for the resulting prediction and a mindful choice of features is recommendable. The final result exhibits values within the range of previously proposed heat flow maps and shows local similarities to the continents once connected to East Antarctica within the supercontinent Gondwana. We suggest a minimum and maximum heat flow map, which can be used as input for ice sheet modeling and sea level rise predictions. : Key Points: A new geothermal heat flow map of Antarctica is established by adopting a machine learning approach. Input features include both global and regional geological and tectonic information, and heat flow observations. A Gondwana reconstruction shows connections of heat flow at the conjugate margins of East Antarctica. : Deutsche Forschungsgemeinschaft (DFG) http://dx.doi.org/10.13039/501100001659
format Text
author Lösing, M.
Ebbing, J.
spellingShingle Lösing, M.
Ebbing, J.
Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach
author_facet Lösing, M.
Ebbing, J.
author_sort Lösing, M.
title Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach
title_short Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach
title_full Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach
title_fullStr Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach
title_full_unstemmed Predicting Geothermal Heat Flow in Antarctica With a Machine Learning Approach
title_sort predicting geothermal heat flow in antarctica with a machine learning approach
publisher FID GEO
publishDate 2021
url https://dx.doi.org/10.23689/fidgeo-5172
https://e-docs.geo-leo.de/handle/11858/9518
geographic Antarctic
East Antarctica
geographic_facet Antarctic
East Antarctica
genre Antarc*
Antarctic
Antarctica
East Antarctica
Ice Sheet
genre_facet Antarc*
Antarctic
Antarctica
East Antarctica
Ice Sheet
op_doi https://doi.org/10.23689/fidgeo-5172
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