Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers

We address the free boundary problem that consists in finding the shape of a three dimensional glacier over a given period and under given climatic conditions. Glacier surface moves by sliding, internal shear and external exchange of mass. Ice is modelled as a non Newtonian fluid. Given the shape of...

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Main Author: Jouvet, Guillaume
Format: Text
Language:French
Published: Lausanne, EPFL 2010
Subjects:
Online Access:https://dx.doi.org/10.5075/epfl-thesis-4677
http://infoscience.epfl.ch/record/146781
id ftdatacite:10.5075/epfl-thesis-4677
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spelling ftdatacite:10.5075/epfl-thesis-4677 2023-05-15T16:41:39+02:00 Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers Jouvet, Guillaume 2010 https://dx.doi.org/10.5075/epfl-thesis-4677 http://infoscience.epfl.ch/record/146781 fr fre Lausanne, EPFL article-journal Text ScholarlyArticle 2010 ftdatacite https://doi.org/10.5075/epfl-thesis-4677 2022-02-08T14:10:01Z We address the free boundary problem that consists in finding the shape of a three dimensional glacier over a given period and under given climatic conditions. Glacier surface moves by sliding, internal shear and external exchange of mass. Ice is modelled as a non Newtonian fluid. Given the shape of the glacier, the velocity of ice is obtained by solving a stationary non-linear Stokes problem with a sliding law along the bedrock-ice interface. The shape of the glacier is updated by computing a Volume Of Fluid (VOF) function, which satisfies a transport equation. Climatic effects (accumulation and ablation of ice) are taken into account in the source term of this equation. A decoupling algorithm with a two-grid method allows the velocity of ice and the VOF to be computed using different numerical techniques, such that a Finite Element Method (FEM) and a characteristics method. On a theoretical level, we prove the well-posedness of the non-linear Stokes problem. A priori estimates for the convergence of the FEM are established by using a quasi-norm technique. Eventually, convergence of the linearisation schemes, such that a fixed point method and a Newton method, is proved. Several applications demonstrate the potential of the numerical method to simulate the motion of a glacier during a long period. The first one consists in the simulation of Rhone et Aletsch glacier from 1880 to 2100 by using climatic data provided by glaciologists. The glacier reconstructions over the last 120 years are validated against measurements. Afterwards, several different climatic scenarios are investigated in order to predict the shape the glaciers until 2100. A dramatic retreat during the 21st century is anticipated for both glaciers. The second application is an inverse problem. It aims to find a climate parametrization allowing a glacier to fit some of its moraines. Two other aspects of glaciology are also addressed in this thesis. The first one consists in modeling and in simulating ice collapse during the calving process. The previous ice flow model is supplemented by a Damage variable which describes the presence of micro crack in ice. An additional numerical scheme allows the Damage field to be solved and a two dimensional simulation of calving to be performed. The second problem aims to prove the existence of stationary ice sheet when considering shallow ice model and a simplified geometry. Numerical investigation confirms the theoretical result and shows physical properties of the solution. Text Ice Sheet DataCite Metadata Store (German National Library of Science and Technology) Rhone ENVELOPE(158.733,158.733,-79.983,-79.983)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language French
description We address the free boundary problem that consists in finding the shape of a three dimensional glacier over a given period and under given climatic conditions. Glacier surface moves by sliding, internal shear and external exchange of mass. Ice is modelled as a non Newtonian fluid. Given the shape of the glacier, the velocity of ice is obtained by solving a stationary non-linear Stokes problem with a sliding law along the bedrock-ice interface. The shape of the glacier is updated by computing a Volume Of Fluid (VOF) function, which satisfies a transport equation. Climatic effects (accumulation and ablation of ice) are taken into account in the source term of this equation. A decoupling algorithm with a two-grid method allows the velocity of ice and the VOF to be computed using different numerical techniques, such that a Finite Element Method (FEM) and a characteristics method. On a theoretical level, we prove the well-posedness of the non-linear Stokes problem. A priori estimates for the convergence of the FEM are established by using a quasi-norm technique. Eventually, convergence of the linearisation schemes, such that a fixed point method and a Newton method, is proved. Several applications demonstrate the potential of the numerical method to simulate the motion of a glacier during a long period. The first one consists in the simulation of Rhone et Aletsch glacier from 1880 to 2100 by using climatic data provided by glaciologists. The glacier reconstructions over the last 120 years are validated against measurements. Afterwards, several different climatic scenarios are investigated in order to predict the shape the glaciers until 2100. A dramatic retreat during the 21st century is anticipated for both glaciers. The second application is an inverse problem. It aims to find a climate parametrization allowing a glacier to fit some of its moraines. Two other aspects of glaciology are also addressed in this thesis. The first one consists in modeling and in simulating ice collapse during the calving process. The previous ice flow model is supplemented by a Damage variable which describes the presence of micro crack in ice. An additional numerical scheme allows the Damage field to be solved and a two dimensional simulation of calving to be performed. The second problem aims to prove the existence of stationary ice sheet when considering shallow ice model and a simplified geometry. Numerical investigation confirms the theoretical result and shows physical properties of the solution.
format Text
author Jouvet, Guillaume
spellingShingle Jouvet, Guillaume
Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers
author_facet Jouvet, Guillaume
author_sort Jouvet, Guillaume
title Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers
title_short Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers
title_full Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers
title_fullStr Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers
title_full_unstemmed Modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers
title_sort modélisation, analyse mathématique et simulation numérique de la dynamique des glaciers
publisher Lausanne, EPFL
publishDate 2010
url https://dx.doi.org/10.5075/epfl-thesis-4677
http://infoscience.epfl.ch/record/146781
long_lat ENVELOPE(158.733,158.733,-79.983,-79.983)
geographic Rhone
geographic_facet Rhone
genre Ice Sheet
genre_facet Ice Sheet
op_doi https://doi.org/10.5075/epfl-thesis-4677
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