A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4)
We present a new, open-source viscoelastic solid earth deformation model, Elmer/Earth. Using the multi-physics finite-element package Elmer, a model to compute viscoelastic material deformation has been implemented into the existing linear elasticity solver routine. Unlike approaches often implement...
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Copernicus GmbH
2020
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ftunivtasmania:oai:eprints.utas.edu.au:32600 2023-05-15T16:41:25+02:00 A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4) Zwinger, T Nield, GA Ruokolainen, J King, MA 2020 application/pdf https://eprints.utas.edu.au/32600/ https://eprints.utas.edu.au/32600/1/137925%20-%20A%20new%20open-source%20viscoelastic%20solid%20earth%20deformation%20module%20implemented%20in%20Elmer%20%28v8.4%29.pdf en eng Copernicus GmbH https://eprints.utas.edu.au/32600/1/137925%20-%20A%20new%20open-source%20viscoelastic%20solid%20earth%20deformation%20module%20implemented%20in%20Elmer%20%28v8.4%29.pdf Zwinger, T, Nield, GA, Ruokolainen, J and King, MA orcid:0000-0001-5611-9498 2020 , 'A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4)' , Geoscientific Model Development, vol. 13 , pp. 1155-1164 , doi:10.5194/gmd-13-1155-2020 <http://dx.doi.org/10.5194/gmd-13-1155-2020>. solid earth deformation glacial isostatic adjustment viscoelasticity Article PeerReviewed 2020 ftunivtasmania https://doi.org/10.5194/gmd-13-1155-2020 2021-07-12T22:16:18Z We present a new, open-source viscoelastic solid earth deformation model, Elmer/Earth. Using the multi-physics finite-element package Elmer, a model to compute viscoelastic material deformation has been implemented into the existing linear elasticity solver routine. Unlike approaches often implemented in engineering codes, our solver accounts for the restoring force of buoyancy within a system of layers with depth-varying density. It does this by directly integrating the solution of the system rather than by applying stress-jump conditions in the form of Winkler foundations on inter-layer boundaries, as is usually needed when solving the minimization problem given by the stress divergence in commercial codes. We benchmarked the new model with results from a commercial finite-element engineering package (ABAQUS, v2018) and another open-source code that uses viscoelastic normal mode theory, TABOO, using a flat-earth setup loaded by a cylindrical disc of 100 km in diameter and 100 m in height at the density of ice. Evaluating the differences in predicted surface deformation at the centre of the load and two distinctive distances (100 and 200 km), average deviations of 7 and 2.7 cm of Elmer/Earth results to ABAQUS and TABOO, respectively, were observed. In view of more than 100 cm maximum vertical deformation and the different numerical methods and parameters, these are very encouraging results. Elmer is set up as a highly scalable parallel code and distributed under the (L)GPL license, meaning that large-scale computations can be made without any licensing restrictions. Scaling figures presented in this paper show good parallel performance of the new model. Additionally, the high-fidelity ice-sheet code Elmer/Ice utilizes the same source base as Elmer and thereby the new model opens the way to undertaking high-resolution coupled ice-flow–solid-earth deformation simulations, which are required for robust projections of future sea-level rise and glacial isostatic adjustment. Article in Journal/Newspaper Ice Sheet University of Tasmania: UTas ePrints Geoscientific Model Development 13 3 1155 1164 |
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Open Polar |
collection |
University of Tasmania: UTas ePrints |
op_collection_id |
ftunivtasmania |
language |
English |
topic |
solid earth deformation glacial isostatic adjustment viscoelasticity |
spellingShingle |
solid earth deformation glacial isostatic adjustment viscoelasticity Zwinger, T Nield, GA Ruokolainen, J King, MA A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4) |
topic_facet |
solid earth deformation glacial isostatic adjustment viscoelasticity |
description |
We present a new, open-source viscoelastic solid earth deformation model, Elmer/Earth. Using the multi-physics finite-element package Elmer, a model to compute viscoelastic material deformation has been implemented into the existing linear elasticity solver routine. Unlike approaches often implemented in engineering codes, our solver accounts for the restoring force of buoyancy within a system of layers with depth-varying density. It does this by directly integrating the solution of the system rather than by applying stress-jump conditions in the form of Winkler foundations on inter-layer boundaries, as is usually needed when solving the minimization problem given by the stress divergence in commercial codes. We benchmarked the new model with results from a commercial finite-element engineering package (ABAQUS, v2018) and another open-source code that uses viscoelastic normal mode theory, TABOO, using a flat-earth setup loaded by a cylindrical disc of 100 km in diameter and 100 m in height at the density of ice. Evaluating the differences in predicted surface deformation at the centre of the load and two distinctive distances (100 and 200 km), average deviations of 7 and 2.7 cm of Elmer/Earth results to ABAQUS and TABOO, respectively, were observed. In view of more than 100 cm maximum vertical deformation and the different numerical methods and parameters, these are very encouraging results. Elmer is set up as a highly scalable parallel code and distributed under the (L)GPL license, meaning that large-scale computations can be made without any licensing restrictions. Scaling figures presented in this paper show good parallel performance of the new model. Additionally, the high-fidelity ice-sheet code Elmer/Ice utilizes the same source base as Elmer and thereby the new model opens the way to undertaking high-resolution coupled ice-flow–solid-earth deformation simulations, which are required for robust projections of future sea-level rise and glacial isostatic adjustment. |
format |
Article in Journal/Newspaper |
author |
Zwinger, T Nield, GA Ruokolainen, J King, MA |
author_facet |
Zwinger, T Nield, GA Ruokolainen, J King, MA |
author_sort |
Zwinger, T |
title |
A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4) |
title_short |
A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4) |
title_full |
A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4) |
title_fullStr |
A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4) |
title_full_unstemmed |
A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4) |
title_sort |
new open-source viscoelastic solid earth deformation module implemented in elmer (v8.4) |
publisher |
Copernicus GmbH |
publishDate |
2020 |
url |
https://eprints.utas.edu.au/32600/ https://eprints.utas.edu.au/32600/1/137925%20-%20A%20new%20open-source%20viscoelastic%20solid%20earth%20deformation%20module%20implemented%20in%20Elmer%20%28v8.4%29.pdf |
genre |
Ice Sheet |
genre_facet |
Ice Sheet |
op_relation |
https://eprints.utas.edu.au/32600/1/137925%20-%20A%20new%20open-source%20viscoelastic%20solid%20earth%20deformation%20module%20implemented%20in%20Elmer%20%28v8.4%29.pdf Zwinger, T, Nield, GA, Ruokolainen, J and King, MA orcid:0000-0001-5611-9498 2020 , 'A new open-source viscoelastic solid earth deformation module implemented in Elmer (v8.4)' , Geoscientific Model Development, vol. 13 , pp. 1155-1164 , doi:10.5194/gmd-13-1155-2020 <http://dx.doi.org/10.5194/gmd-13-1155-2020>. |
op_doi |
https://doi.org/10.5194/gmd-13-1155-2020 |
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Geoscientific Model Development |
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13 |
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3 |
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1155 |
op_container_end_page |
1164 |
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1766031853063503872 |