Pine Island Glacier : a 3D full-Stokes model study

Mass loss from the Antarctic Ice Sheet is found to significantly contribute to eustatic sea level rise, due to a dynamic response in the system. Pine Island Glacier, a fast flowing outlet glacier in the West Antarctic Ice Sheet, is located in the Amundsen Sea Embayment Area, where the present Antarc...

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Bibliographic Details
Main Author: Wilkens, Nina
Other Authors: Humbert, Angelika (Prof. Dr.)
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: Staats- und Universitätsbibliothek Hamburg Carl von Ossietzky 2014
Subjects:
Pine Island Gletscher
Westantarktisches Eisschild
Marines Eisschild
full-Stokes Model
Basales Gleiten
Glaciology
Antarctica
Ice dynamics
Modelling
Pine Island Glacier
550 Geowissenschaften
30.03 Methoden und Techniken in den Naturwissenschaften
31.76 Numerische Mathematik
31.80 Angewandte Mathematik
33.14 Kontinuumsphysik
38.43 Gletscherkunde
Glaziologie
Modellierung
Antarktis
Gletscher
Eis
Strömungsmechanik
Finite-Elemente-Methode
Kontinuumsmechanik
ddc:550
Antarctic
The Antarctic
Amundsen Sea
West Antarctic Ice Sheet
Antarc*
Antarktis*
Eisschild*
Ice Sheet
Ice Shelf
Pine Island
Online Access:http://nbn-resolving.de/urn:nbn:de:gbv:18-67350
https://ediss.sub.uni-hamburg.de/handle/ediss/5397
Description
Summary:Mass loss from the Antarctic Ice Sheet is found to significantly contribute to eustatic sea level rise, due to a dynamic response in the system. Pine Island Glacier, a fast flowing outlet glacier in the West Antarctic Ice Sheet, is located in the Amundsen Sea Embayment Area, where the present Antarctic mass loss is concentrated. The observed mass loss in the area coincides with acceleration and thinning of the glacier, accompanied by a retreat of the grounding line, which is the line of separation between grounded and floating ice. The bed beneath the glacier lies in large parts below sea level, with the bed sloping down away from the ocean. This setting makes the glacier especially vulnerable to increasing and possibly accelerating retreat. Remote sensing techniques allow only for the surface conditions of glacial systems to be nowadays monitored over reasonable temporal and spatial scales. The conditions at the base, however, are still widely unknown, due to their inaccessibility. This poses a challenge, as basal conditions are a very important component for understanding glacier dynamics. A key technique to bridge this challenge is given by numerical modelling. In glaciological studies flow models are developed, that can either be used to solve in a prognostic manner over long time scales, being based on approximations to the full system of equations, or to solve diagnostically in high resolution for the full system, to study processes in more detail. Here we present a model of the later category, a thermo-mechanically coupled 3D full-Stokes ice flow model, which is set up to the region of Pine Island Glacier. It is solved with the finite element method, and the prismatic mesh is refined horizontally across the grounding line, where high resolution is needed. With this coupled flow model we assess the present thermal and dynamical state of the coupled ice sheet - ice shelf system. Furthermore, we develop a method to include measured basal properties into the formulation of the basal sliding law. We find the ...

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