A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications
Relative sea-level variations during the late Pleistocene can only be reconstructed with the knowledge of ice-sheet history. On the other hand, the knowledge of regional and global relative sea-level variations is necessary to learn about the changes in ice volume. Overcoming this problem of circula...
| Published in: | Geoscientific Model Development |
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| Format: | Text |
| Language: | English |
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2018
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| Online Access: | https://doi.org/10.5194/gmd-7-2141-2014 https://gmd.copernicus.org/articles/7/2141/2014/ |
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ftcopernicus:oai:publications.copernicus.org:gmd25389 |
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ftcopernicus:oai:publications.copernicus.org:gmd25389 2023-05-15T13:54:27+02:00 A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications de Boer, B. Stocchi, P. van de Wal, R. S. W. 2018-09-27 application/pdf https://doi.org/10.5194/gmd-7-2141-2014 https://gmd.copernicus.org/articles/7/2141/2014/ eng eng doi:10.5194/gmd-7-2141-2014 https://gmd.copernicus.org/articles/7/2141/2014/ eISSN: 1991-9603 Text 2018 ftcopernicus https://doi.org/10.5194/gmd-7-2141-2014 2020-07-20T16:24:55Z Relative sea-level variations during the late Pleistocene can only be reconstructed with the knowledge of ice-sheet history. On the other hand, the knowledge of regional and global relative sea-level variations is necessary to learn about the changes in ice volume. Overcoming this problem of circularity demands a fully coupled system where ice sheets and sea level vary consistently in space and time and dynamically affect each other. Here we present results for the past 410 000 years (410 kyr) from the coupling of a set of 3-D ice-sheet-shelf models to a global sea-level model, which is based on the solution of the gravitationally self-consistent sea-level equation. The sea-level model incorporates the glacial isostatic adjustment feedbacks for a Maxwell viscoelastic and rotating Earth model with coastal migration. Ice volume is computed with four 3-D ice-sheet-shelf models for North America, Eurasia, Greenland and Antarctica. Using an inverse approach, ice volume and temperature are derived from a benthic δ 18 O stacked record. The derived surface-air temperature anomaly is added to the present-day climatology to simulate glacial–interglacial changes in temperature and hence ice volume. The ice-sheet thickness variations are then forwarded to the sea-level model to compute the bedrock deformation, the change in sea-surface height and thus the relative sea-level change. The latter is then forwarded to the ice-sheet models. To quantify the impact of relative sea-level variations on ice-volume evolution, we have performed coupled and uncoupled simulations. The largest differences of ice-sheet thickness change occur at the edges of the ice sheets, where relative sea-level change significantly departs from the ocean-averaged sea-level variations. Text Antarc* Antarctica Greenland Ice Sheet Copernicus Publications: E-Journals Greenland Geoscientific Model Development 7 5 2141 2156 |
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Open Polar |
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Copernicus Publications: E-Journals |
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ftcopernicus |
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English |
| description |
Relative sea-level variations during the late Pleistocene can only be reconstructed with the knowledge of ice-sheet history. On the other hand, the knowledge of regional and global relative sea-level variations is necessary to learn about the changes in ice volume. Overcoming this problem of circularity demands a fully coupled system where ice sheets and sea level vary consistently in space and time and dynamically affect each other. Here we present results for the past 410 000 years (410 kyr) from the coupling of a set of 3-D ice-sheet-shelf models to a global sea-level model, which is based on the solution of the gravitationally self-consistent sea-level equation. The sea-level model incorporates the glacial isostatic adjustment feedbacks for a Maxwell viscoelastic and rotating Earth model with coastal migration. Ice volume is computed with four 3-D ice-sheet-shelf models for North America, Eurasia, Greenland and Antarctica. Using an inverse approach, ice volume and temperature are derived from a benthic δ 18 O stacked record. The derived surface-air temperature anomaly is added to the present-day climatology to simulate glacial–interglacial changes in temperature and hence ice volume. The ice-sheet thickness variations are then forwarded to the sea-level model to compute the bedrock deformation, the change in sea-surface height and thus the relative sea-level change. The latter is then forwarded to the ice-sheet models. To quantify the impact of relative sea-level variations on ice-volume evolution, we have performed coupled and uncoupled simulations. The largest differences of ice-sheet thickness change occur at the edges of the ice sheets, where relative sea-level change significantly departs from the ocean-averaged sea-level variations. |
| format |
Text |
| author |
de Boer, B. Stocchi, P. van de Wal, R. S. W. |
| spellingShingle |
de Boer, B. Stocchi, P. van de Wal, R. S. W. A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications |
| author_facet |
de Boer, B. Stocchi, P. van de Wal, R. S. W. |
| author_sort |
de Boer, B. |
| title |
A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications |
| title_short |
A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications |
| title_full |
A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications |
| title_fullStr |
A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications |
| title_full_unstemmed |
A fully coupled 3-D ice-sheet–sea-level model: algorithm and applications |
| title_sort |
fully coupled 3-d ice-sheet–sea-level model: algorithm and applications |
| publishDate |
2018 |
| url |
https://doi.org/10.5194/gmd-7-2141-2014 https://gmd.copernicus.org/articles/7/2141/2014/ |
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Greenland |
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Greenland |
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Antarc* Antarctica Greenland Ice Sheet |
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Antarc* Antarctica Greenland Ice Sheet |
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eISSN: 1991-9603 |
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doi:10.5194/gmd-7-2141-2014 https://gmd.copernicus.org/articles/7/2141/2014/ |
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https://doi.org/10.5194/gmd-7-2141-2014 |
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Geoscientific Model Development |
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2141 |
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2156 |
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