Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data

Probabilistic predictions of the sea level contribution from Antarctica often have large uncertainty intervals. Calibration of model simulations with observations can reduce uncertainties and improve confidence in projections, particularly if this exploits as much of the available information as pos...

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Published in:	The Cryosphere
Main Authors:	Wernecke, Andreas, Edwards, Tamsin L., Nias, Isabel J., Holden, Philip B., Edwards, Neil R.
Format:	Text
Language:	English
Published:	2020
Subjects:	Antarctic Amundsen Sea Pine Island Glacier Antarc* Antarctica Ice Sheet Pine Island
Online Access:	https://doi.org/10.5194/tc-14-1459-2020 https://tc.copernicus.org/articles/14/1459/2020/

id	ftcopernicus:oai:publications.copernicus.org:tc77742
record_format	openpolar
spelling	ftcopernicus:oai:publications.copernicus.org:tc77742 2023-05-15T13:24:04+02:00 Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data Wernecke, Andreas Edwards, Tamsin L. Nias, Isabel J. Holden, Philip B. Edwards, Neil R. 2020-05-05 application/pdf https://doi.org/10.5194/tc-14-1459-2020 https://tc.copernicus.org/articles/14/1459/2020/ eng eng doi:10.5194/tc-14-1459-2020 https://tc.copernicus.org/articles/14/1459/2020/ eISSN: 1994-0424 Text 2020 ftcopernicus https://doi.org/10.5194/tc-14-1459-2020 2020-07-20T16:22:11Z Probabilistic predictions of the sea level contribution from Antarctica often have large uncertainty intervals. Calibration of model simulations with observations can reduce uncertainties and improve confidence in projections, particularly if this exploits as much of the available information as possible (such as spatial characteristics), but the necessary statistical treatment is often challenging and can be computationally prohibitive. Ice sheet models with sufficient spatial resolution to resolve grounding line evolution are also computationally expensive. Here we address these challenges by adopting and comparing dimension-reduced calibration approaches based on a principal component decomposition of the adaptive mesh model BISICLES. The effects model parameters have on these principal components are then gathered in statistical emulators to allow for smooth probability density estimates. With the help of a published perturbed parameter ice sheet model ensemble of the Amundsen Sea Embayment (ASE), we show how the use of principal components in combination with spatially resolved observations can improve probabilistic calibrations. In synthetic model experiments (calibrating the model with altered model results) we can identify the correct basal traction and ice viscosity scaling parameters as well as the bedrock map with spatial calibrations. In comparison a simpler calibration against an aggregated observation, the net sea level contribution, imposes only weaker constraints by allowing a wide range of basal traction and viscosity scaling factors. Uncertainties in sea level rise contribution of 50-year simulations from the current state of the ASE can be reduced with satellite observations of recent ice thickness change by nearly 90 %; median and 90 % confidence intervals are 18.9 [13.9, 24.8] mm SLE (sea level equivalent) for the proposed spatial calibration approach, 16.8 [7.7, 25.6] mm SLE for the net sea level calibration and 23.1 [ −8.4 , 94.5] mm SLE for the uncalibrated ensemble. The spatial model behaviour is much more consistent with observations if, instead of Bedmap2, a modified bedrock topography is used that most notably removes a topographic rise near the initial grounding line of Pine Island Glacier. The ASE dominates the current Antarctic sea level contribution, but other regions have the potential to become more important on centennial scales. These larger spatial and temporal scales would benefit even more from methods of fast but exhaustive model calibration. Applied to projections of the whole Antarctic ice sheet, our approach has therefore the potential to efficiently improve our understanding of model behaviour, as well as substantiating and reducing projection uncertainties. Text Amundsen Sea Antarc* Antarctic Antarctica Ice Sheet Pine Island Pine Island Glacier Copernicus Publications: E-Journals Antarctic Amundsen Sea Pine Island Glacier ENVELOPE(-101.000,-101.000,-75.000,-75.000) The Cryosphere 14 5 1459 1474
institution	Open Polar
collection	Copernicus Publications: E-Journals
op_collection_id	ftcopernicus
language	English
description	Probabilistic predictions of the sea level contribution from Antarctica often have large uncertainty intervals. Calibration of model simulations with observations can reduce uncertainties and improve confidence in projections, particularly if this exploits as much of the available information as possible (such as spatial characteristics), but the necessary statistical treatment is often challenging and can be computationally prohibitive. Ice sheet models with sufficient spatial resolution to resolve grounding line evolution are also computationally expensive. Here we address these challenges by adopting and comparing dimension-reduced calibration approaches based on a principal component decomposition of the adaptive mesh model BISICLES. The effects model parameters have on these principal components are then gathered in statistical emulators to allow for smooth probability density estimates. With the help of a published perturbed parameter ice sheet model ensemble of the Amundsen Sea Embayment (ASE), we show how the use of principal components in combination with spatially resolved observations can improve probabilistic calibrations. In synthetic model experiments (calibrating the model with altered model results) we can identify the correct basal traction and ice viscosity scaling parameters as well as the bedrock map with spatial calibrations. In comparison a simpler calibration against an aggregated observation, the net sea level contribution, imposes only weaker constraints by allowing a wide range of basal traction and viscosity scaling factors. Uncertainties in sea level rise contribution of 50-year simulations from the current state of the ASE can be reduced with satellite observations of recent ice thickness change by nearly 90 %; median and 90 % confidence intervals are 18.9 [13.9, 24.8] mm SLE (sea level equivalent) for the proposed spatial calibration approach, 16.8 [7.7, 25.6] mm SLE for the net sea level calibration and 23.1 [ −8.4 , 94.5] mm SLE for the uncalibrated ensemble. The spatial model behaviour is much more consistent with observations if, instead of Bedmap2, a modified bedrock topography is used that most notably removes a topographic rise near the initial grounding line of Pine Island Glacier. The ASE dominates the current Antarctic sea level contribution, but other regions have the potential to become more important on centennial scales. These larger spatial and temporal scales would benefit even more from methods of fast but exhaustive model calibration. Applied to projections of the whole Antarctic ice sheet, our approach has therefore the potential to efficiently improve our understanding of model behaviour, as well as substantiating and reducing projection uncertainties.
format	Text
author	Wernecke, Andreas Edwards, Tamsin L. Nias, Isabel J. Holden, Philip B. Edwards, Neil R.
spellingShingle	Wernecke, Andreas Edwards, Tamsin L. Nias, Isabel J. Holden, Philip B. Edwards, Neil R. Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data
author_facet	Wernecke, Andreas Edwards, Tamsin L. Nias, Isabel J. Holden, Philip B. Edwards, Neil R.
author_sort	Wernecke, Andreas
title	Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data
title_short	Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data
title_full	Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data
title_fullStr	Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data
title_full_unstemmed	Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data
title_sort	spatial probabilistic calibration of a high-resolution amundsen sea embayment ice sheet model with satellite altimeter data
publishDate	2020
url	https://doi.org/10.5194/tc-14-1459-2020 https://tc.copernicus.org/articles/14/1459/2020/
long_lat	ENVELOPE(-101.000,-101.000,-75.000,-75.000)
geographic	Antarctic Amundsen Sea Pine Island Glacier
geographic_facet	Antarctic Amundsen Sea Pine Island Glacier
genre	Amundsen Sea Antarc* Antarctic Antarctica Ice Sheet Pine Island Pine Island Glacier
genre_facet	Amundsen Sea Antarc* Antarctic Antarctica Ice Sheet Pine Island Pine Island Glacier
op_source	eISSN: 1994-0424
op_relation	doi:10.5194/tc-14-1459-2020 https://tc.copernicus.org/articles/14/1459/2020/
op_doi	https://doi.org/10.5194/tc-14-1459-2020
container_title	The Cryosphere
container_volume	14
container_issue	5
container_start_page	1459
op_container_end_page	1474
_version_	1766377266804162560

Spatial probabilistic calibration of a high-resolution Amundsen Sea Embayment ice sheet model with satellite altimeter data

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