C33A-0367:
DynEarthSol3D: numerical studies of basal crevasses and calving blocks

Wednesday, 17 December 2014
Elizabeth Logan1, Luc L Lavier2, Eunseo Choi3, Eh Tan4 and Ginny A Catania1, (1)University of Texas at Austin, Austin, TX, United States, (2)Jackson School of Geosciences, Austin, TX, United States, (3)University of Memphis, Memphis, TN, United States, (4)Academia Sinica, Taipei, Taiwan
Abstract:
DynEarthSol3D (DES) is a thermomechanical model for the simulation of dynamic ice flow. We present the application of DES toward two case studies – basal crevasses and calving blocks – to illustrate the potential of the model to aid in understanding calving processes. Among the advantages of using DES are: its unstructured meshes which adaptively resolve zones of high interest; its use of multiple rheologies to simulate different types of dynamic behavior; and its explicit and parallel numerical core which both make the implementation of different boundary conditions easy and the model highly scalable.

We examine the initiation and development of both basal crevasses and calving blocks through time using visco-elasto-plastic rheology. Employing a brittle-to-ductile transition zone (BDTZ) based on local strain rate shows that the style and development of brittle features like crevasses differs markedly on the rheological parameters. Brittle and ductile behavior are captured by Mohr-Coulomb elastoplasticity and Maxwell viscoelasticity, respectively. We explore the parameter spaces which define these rheologies (including temperature) as well as the BDTZ threshold (shown in the literature as 10-7 Pa s), using time-to-failure as a metric for accuracy within the model. As the time it takes for a block of ice to fail can determine an iceberg’s size, this work has implications for calving laws.