What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow.
This research involves a few First-Order System Least Squares (FOSLS) formulations of a nonlinear-Stokes flow model for ice sheets. In Glen's flow law, a commonly used constitutive equation for ice rheology, the viscosity becomes infinite as the velocity gradients approach zero. This typically...
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| Format: | Text |
| Language: | unknown |
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CU Scholar
2017
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| Online Access: | https://scholar.colorado.edu/appm_gradetds/125 https://scholar.colorado.edu/cgi/viewcontent.cgi?article=1135&context=appm_gradetds |
| _version_ | 1821543882876256256 |
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| author | Allen, Jeffery M. |
| author_facet | Allen, Jeffery M. |
| author_sort | Allen, Jeffery M. |
| collection | University of Colorado, Boulder: CU Scholar |
| description | This research involves a few First-Order System Least Squares (FOSLS) formulations of a nonlinear-Stokes flow model for ice sheets. In Glen's flow law, a commonly used constitutive equation for ice rheology, the viscosity becomes infinite as the velocity gradients approach zero. This typically occurs near the ice surface or where there is basal sliding. The computational difficulties associated with the infinite viscosity are often overcome by an arbitrary modification of Glen's law that bounds the maximum viscosity. The FOSLS formulations developed in this thesis are designed to overcome this difficulty. The first FOSLS formulation is just the first-order representation of the standard nonlinear, full-Stokes and is known as the viscosity formulation and suffers from the problem above. To overcome the problem of infinite viscosity, two new formulation exploit the fact that the deviatoric stress, the product of viscosity and strain-rate, approaches zero as the viscosity goes to infinity. Using the deviatoric stress as the basis for a first-order system results in the the basic fluidity system. Augmenting the basic fluidity system with a curl-type equation results in the augmented fluidity system, which is more amenable to the iterative solver, Algebraic MultiGrid (AMG). A Nested Iteration (NI) Newton-FOSLS-AMG approach is used to solve the nonlinear-Stokes problems. Several test problems from the ISMIP set of benchmarks is examined to test the effectiveness of the various formulations. These test show that the viscosity based method is more expensive and less accurate. The basic fluidity system shows optimal finite-element convergence. However, there is not yet an efficient iterative solver for this type of system and this is the topic of future research. Alternatively, AMG performs better on the augmented fluidity system when using specific scaling. Unfortunately, this scaling results in reduced finite-element convergence. |
| format | Text |
| genre | Ice Sheet |
| genre_facet | Ice Sheet |
| geographic | Curl |
| geographic_facet | Curl |
| id | ftunicolboulder:oai:scholar.colorado.edu:appm_gradetds-1135 |
| institution | Open Polar |
| language | unknown |
| long_lat | ENVELOPE(-63.071,-63.071,-70.797,-70.797) |
| op_collection_id | ftunicolboulder |
| op_relation | https://scholar.colorado.edu/appm_gradetds/125 https://scholar.colorado.edu/cgi/viewcontent.cgi?article=1135&context=appm_gradetds |
| op_source | Applied Mathematics Graduate Theses & Dissertations |
| publishDate | 2017 |
| publisher | CU Scholar |
| record_format | openpolar |
| spelling | ftunicolboulder:oai:scholar.colorado.edu:appm_gradetds-1135 2025-01-16T22:27:15+00:00 What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow. Allen, Jeffery M. 2017-01-01T08:00:00Z application/pdf https://scholar.colorado.edu/appm_gradetds/125 https://scholar.colorado.edu/cgi/viewcontent.cgi?article=1135&context=appm_gradetds unknown CU Scholar https://scholar.colorado.edu/appm_gradetds/125 https://scholar.colorado.edu/cgi/viewcontent.cgi?article=1135&context=appm_gradetds Applied Mathematics Graduate Theses & Dissertations fluid flow fosls glaciers ice sheets multigrid nonlinear stokes equations Mathematics Non-linear Dynamics text 2017 ftunicolboulder 2018-12-08T00:30:28Z This research involves a few First-Order System Least Squares (FOSLS) formulations of a nonlinear-Stokes flow model for ice sheets. In Glen's flow law, a commonly used constitutive equation for ice rheology, the viscosity becomes infinite as the velocity gradients approach zero. This typically occurs near the ice surface or where there is basal sliding. The computational difficulties associated with the infinite viscosity are often overcome by an arbitrary modification of Glen's law that bounds the maximum viscosity. The FOSLS formulations developed in this thesis are designed to overcome this difficulty. The first FOSLS formulation is just the first-order representation of the standard nonlinear, full-Stokes and is known as the viscosity formulation and suffers from the problem above. To overcome the problem of infinite viscosity, two new formulation exploit the fact that the deviatoric stress, the product of viscosity and strain-rate, approaches zero as the viscosity goes to infinity. Using the deviatoric stress as the basis for a first-order system results in the the basic fluidity system. Augmenting the basic fluidity system with a curl-type equation results in the augmented fluidity system, which is more amenable to the iterative solver, Algebraic MultiGrid (AMG). A Nested Iteration (NI) Newton-FOSLS-AMG approach is used to solve the nonlinear-Stokes problems. Several test problems from the ISMIP set of benchmarks is examined to test the effectiveness of the various formulations. These test show that the viscosity based method is more expensive and less accurate. The basic fluidity system shows optimal finite-element convergence. However, there is not yet an efficient iterative solver for this type of system and this is the topic of future research. Alternatively, AMG performs better on the augmented fluidity system when using specific scaling. Unfortunately, this scaling results in reduced finite-element convergence. Text Ice Sheet University of Colorado, Boulder: CU Scholar Curl ENVELOPE(-63.071,-63.071,-70.797,-70.797) |
| spellingShingle | fluid flow fosls glaciers ice sheets multigrid nonlinear stokes equations Mathematics Non-linear Dynamics Allen, Jeffery M. What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow. |
| title | What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow. |
| title_full | What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow. |
| title_fullStr | What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow. |
| title_full_unstemmed | What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow. |
| title_short | What's Cooler Than Being Cool? Ice-Sheet Models Using a Fluidity-Based FOSLS Approach to Nonlinear-Stokes Flow. |
| title_sort | what's cooler than being cool? ice-sheet models using a fluidity-based fosls approach to nonlinear-stokes flow. |
| topic | fluid flow fosls glaciers ice sheets multigrid nonlinear stokes equations Mathematics Non-linear Dynamics |
| topic_facet | fluid flow fosls glaciers ice sheets multigrid nonlinear stokes equations Mathematics Non-linear Dynamics |
| url | https://scholar.colorado.edu/appm_gradetds/125 https://scholar.colorado.edu/cgi/viewcontent.cgi?article=1135&context=appm_gradetds |