Simulating ice processes using the finite element, unstructured, adaptive model fluidity

The cryosphere impacts global climate in various ways. Snow and ice have a higher albedo than land or the open ocean and therefore affect the total reflectivity of the earth. Sea ice forms an insulating layer over the polar oceans controlling both heat and water vapour fluxes between the atmosphere...

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Main Author: Mouradian, Simon
Format: Text
Language:unknown
Published: Imperial College London 2014
Subjects:
Greenland
Alfred Wegener Institute
glacier
Ice Sheet
Sea ice
Online Access:https://dx.doi.org/10.25560/24846
http://spiral.imperial.ac.uk/handle/10044/1/24846
id ftdatacite:10.25560/24846
record_format openpolar
spelling ftdatacite:10.25560/24846 2023-05-15T13:15:42+02:00 Simulating ice processes using the finite element, unstructured, adaptive model fluidity Mouradian, Simon 2014 https://dx.doi.org/10.25560/24846 http://spiral.imperial.ac.uk/handle/10044/1/24846 unknown Imperial College London Text ScholarlyArticle article-journal Doctor of Philosophy (PhD) 2014 ftdatacite https://doi.org/10.25560/24846 2021-11-05T12:55:41Z The cryosphere impacts global climate in various ways. Snow and ice have a higher albedo than land or the open ocean and therefore affect the total reflectivity of the earth. Sea ice forms an insulating layer over the polar oceans controlling both heat and water vapour fluxes between the atmosphere and polar ocean. Ice sheets hold around 77% of Earth's freshwater reserves, and recent increases in ice loss from the Earth's ice sheets are cause for concern. This thesis develops numerical tools that can be used for the study of various ice processes such as ocean -- sea ice interaction, ice sheet and glacier dynamics. A coupled ocean - sea ice model is developed, using the open source, unstructured, adaptive ocean model Fluidity and a finite element sea ice model developed at the Alfred Wegener Institute of Polar and Marine Research, FESIM. The tightly coupled model is verified and validated through a series of tests, demonstrating its dynamical capabilities. The sea ice dynamics are a model of Elastic-Viscous-Plastic rheology, as described in Hunke and Dukowicz. The thermodynamic parameterisation is similar to the 1D simplest model of Parkinson and Washington which is based on the zero-layer approach of Semtner. Furthermore, a new computational framework for carrying out ice sheet simulations is presented. A thermo-mechanical, non-linear, full-Stokes model is used to carry out the exercises of the Ice Sheet Model Intercomparison Project for higher--order models (ISMIP--HOM). The results presented here show that Fluidity compares favourably with other ice sheet models. Further tests are performed to demonstrate the use of dynamic adaptive remeshing in lowering the computational cost of models compared to their structured, fixed-mesh counterparts, by focusing resolution only where and when required. Finally, initial simulations of the full Greenland ice sheet are performed demonstrating the potential utility of adaptive meshes for large-scale, full-Stokes modelling. Text Alfred Wegener Institute glacier Greenland Ice Sheet Sea ice DataCite Metadata Store (German National Library of Science and Technology) Greenland
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
description The cryosphere impacts global climate in various ways. Snow and ice have a higher albedo than land or the open ocean and therefore affect the total reflectivity of the earth. Sea ice forms an insulating layer over the polar oceans controlling both heat and water vapour fluxes between the atmosphere and polar ocean. Ice sheets hold around 77% of Earth's freshwater reserves, and recent increases in ice loss from the Earth's ice sheets are cause for concern. This thesis develops numerical tools that can be used for the study of various ice processes such as ocean -- sea ice interaction, ice sheet and glacier dynamics. A coupled ocean - sea ice model is developed, using the open source, unstructured, adaptive ocean model Fluidity and a finite element sea ice model developed at the Alfred Wegener Institute of Polar and Marine Research, FESIM. The tightly coupled model is verified and validated through a series of tests, demonstrating its dynamical capabilities. The sea ice dynamics are a model of Elastic-Viscous-Plastic rheology, as described in Hunke and Dukowicz. The thermodynamic parameterisation is similar to the 1D simplest model of Parkinson and Washington which is based on the zero-layer approach of Semtner. Furthermore, a new computational framework for carrying out ice sheet simulations is presented. A thermo-mechanical, non-linear, full-Stokes model is used to carry out the exercises of the Ice Sheet Model Intercomparison Project for higher--order models (ISMIP--HOM). The results presented here show that Fluidity compares favourably with other ice sheet models. Further tests are performed to demonstrate the use of dynamic adaptive remeshing in lowering the computational cost of models compared to their structured, fixed-mesh counterparts, by focusing resolution only where and when required. Finally, initial simulations of the full Greenland ice sheet are performed demonstrating the potential utility of adaptive meshes for large-scale, full-Stokes modelling.
format Text
author Mouradian, Simon
spellingShingle Mouradian, Simon
Simulating ice processes using the finite element, unstructured, adaptive model fluidity
author_facet Mouradian, Simon
author_sort Mouradian, Simon
title Simulating ice processes using the finite element, unstructured, adaptive model fluidity
title_short Simulating ice processes using the finite element, unstructured, adaptive model fluidity
title_full Simulating ice processes using the finite element, unstructured, adaptive model fluidity
title_fullStr Simulating ice processes using the finite element, unstructured, adaptive model fluidity
title_full_unstemmed Simulating ice processes using the finite element, unstructured, adaptive model fluidity
title_sort simulating ice processes using the finite element, unstructured, adaptive model fluidity
publisher Imperial College London
publishDate 2014
url https://dx.doi.org/10.25560/24846
http://spiral.imperial.ac.uk/handle/10044/1/24846
geographic Greenland
geographic_facet Greenland
genre Alfred Wegener Institute
glacier
Greenland
Ice Sheet
Sea ice
genre_facet Alfred Wegener Institute
glacier
Greenland
Ice Sheet
Sea ice
op_doi https://doi.org/10.25560/24846
_version_ 1766270628739940352

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