Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties

Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties

<p>Antarctic ice shelves are vulnerable to warming ocean temperatures, and some have already begun thinning in response to increased basal melt rates. Sea level is therefore expected to rise due to Antarctic contributions, but uncertainties in its amount and timing remain largely unquantified....

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Main Authors: M. Berdahl, G. Leguy, W. H. Lipscomb, N. M. Urban
Format: Article
Language:English
Published: Copernicus Publications 2021-06-01
Series:The Cryosphere
Online Access:https://tc.copernicus.org/articles/15/2683/2021/tc-15-2683-2021.pdf
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spelling doaj-931780efabaa40ac8f49d1b98a7324dc2021-06-15T12:17:12ZengCopernicus PublicationsThe Cryosphere1994-04161994-04242021-06-01152683269910.5194/tc-15-2683-2021Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertaintiesM. Berdahl0M. Berdahl1G. Leguy2W. H. Lipscomb3N. M. Urban4N. M. Urban5Department of Earth and Space Sciences, University of Washington, Seattle, WA, USAComputational Physics and Methods Group, Los Alamos National Laboratory, Los Alamos, NM, USAClimate and Global Dynamics Laboratory, National Center for Atmospheric Research, Boulder, CO, USAClimate and Global Dynamics Laboratory, National Center for Atmospheric Research, Boulder, CO, USAComputational Physics and Methods Group, Los Alamos National Laboratory, Los Alamos, NM, USAComputational Science Initiative, Brookhaven National Laboratory, Upton, NY, USA<p>Antarctic ice shelves are vulnerable to warming ocean temperatures, and some have already begun thinning in response to increased basal melt rates. Sea level is therefore expected to rise due to Antarctic contributions, but uncertainties in its amount and timing remain largely unquantified. In particular, there is substantial uncertainty in future basal melt rates arising from multi-model differences in thermal forcing and how melt rates depend on that thermal forcing. To facilitate uncertainty quantification in sea level rise projections, we build, validate, and demonstrate projections from a computationally efficient statistical emulator of a high-resolution (4 km) Antarctic ice sheet model, the Community Ice Sheet Model version 2.1. The emulator is trained to a large (500-member) ensemble of 200-year-long 4 km resolution transient ice sheet simulations, whereby regional basal melt rates are perturbed by idealized (yet physically informed) trajectories. The main advantage of our emulation approach is that by sampling a wide range of possible basal melt trajectories, the emulator can be used to (1) produce probabilistic sea level rise projections over much larger Monte Carlo ensembles than are possible by direct numerical simulation alone, thereby providing better statistical characterization of uncertainties, and (2) predict the simulated ice sheet response under differing assumptions about basal melt characteristics as new oceanographic studies are published, without having to run additional numerical ice sheet simulations. As a proof of concept, we propagate uncertainties about future basal melt rate trajectories, derived from regional ocean models, to generate probabilistic sea level rise estimates for 100 and 200 years into the future.</p>https://tc.copernicus.org/articles/15/2683/2021/tc-15-2683-2021.pdf
collection DOAJ
language English
format Article
sources DOAJ
author M. Berdahl
M. Berdahl
G. Leguy
W. H. Lipscomb
N. M. Urban
N. M. Urban
spellingShingle M. Berdahl
M. Berdahl
G. Leguy
W. H. Lipscomb
N. M. Urban
N. M. Urban
Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties
The Cryosphere
author_facet M. Berdahl
M. Berdahl
G. Leguy
W. H. Lipscomb
N. M. Urban
N. M. Urban
author_sort M. Berdahl
title Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties
title_short Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties
title_full Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties
title_fullStr Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties
title_full_unstemmed Statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify Antarctic sea level rise uncertainties
title_sort statistical emulation of a perturbed basal melt ensemble of an ice sheet model to better quantify antarctic sea level rise uncertainties
publisher Copernicus Publications
series The Cryosphere
issn 1994-0416
1994-0424
publishDate 2021-06-01
description <p>Antarctic ice shelves are vulnerable to warming ocean temperatures, and some have already begun thinning in response to increased basal melt rates. Sea level is therefore expected to rise due to Antarctic contributions, but uncertainties in its amount and timing remain largely unquantified. In particular, there is substantial uncertainty in future basal melt rates arising from multi-model differences in thermal forcing and how melt rates depend on that thermal forcing. To facilitate uncertainty quantification in sea level rise projections, we build, validate, and demonstrate projections from a computationally efficient statistical emulator of a high-resolution (4 km) Antarctic ice sheet model, the Community Ice Sheet Model version 2.1. The emulator is trained to a large (500-member) ensemble of 200-year-long 4 km resolution transient ice sheet simulations, whereby regional basal melt rates are perturbed by idealized (yet physically informed) trajectories. The main advantage of our emulation approach is that by sampling a wide range of possible basal melt trajectories, the emulator can be used to (1) produce probabilistic sea level rise projections over much larger Monte Carlo ensembles than are possible by direct numerical simulation alone, thereby providing better statistical characterization of uncertainties, and (2) predict the simulated ice sheet response under differing assumptions about basal melt characteristics as new oceanographic studies are published, without having to run additional numerical ice sheet simulations. As a proof of concept, we propagate uncertainties about future basal melt rate trajectories, derived from regional ocean models, to generate probabilistic sea level rise estimates for 100 and 200 years into the future.</p>
url https://tc.copernicus.org/articles/15/2683/2021/tc-15-2683-2021.pdf
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