Staff profile
Bradley Sims
Research Postgraduate - Computational Mechanics Node
Affiliation |
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Research Postgraduate - Computational Mechanics Node in the Department of Engineering |
Biography
Bradley is a PhD student in the Department of Engineering, specialising in computational mechanics. He studied his undergraduate degree in Durham, graduating with a first class MEng degree in Aeronautical Engineering in 2020, before returning to begin his PhD in 2022. As a part of his undergraduate final year project, Bradley investigated the relative performance of implicit and explicit time stepping schemes in the Material Point Method.
Research Project
Iceberg calving is a complex natural fracture process which is responsible for half of the mass lost from floating ice shelves and glaciers in Greenland and Antarctica. There is concern that rapid changes in these ice zones could ultimately lead to rapid sea level rise over the coming years.
The goal of Bradley's project is develop a new computational approach for the accurate and efficient simulation of crack propagation in glacier ice, using a Phase Field model with a mesh-adaptive discontininous Galerkin finite element method (DG-FEM).
Publications
Conference Paper
- Sims, B., Bird, R. E., Coombs, W. M., & Giani, S. (2024, April). Immersed traction boundary conditions in phase field fracture modelling. Presented at 2024 UK Association for Computational Mechanics Conference, Durham, UK
- Sims, B., Bird, R., Giani, S., & Coombs, W. (2023, April). An investigation into the methods for modelling pre-existing cracks in phase field problems. Presented at UKACM 2023, Warwick, UK
Journal Article
- Bird, R. E., Augarde, C. E., Coombs, W. M., Duddu, R., Giani, S., Huynh, P. T., & Sims, B. (2023). An hp-adaptive discontinuous Galerkin method for phase field fracture. Computer Methods in Applied Mechanics and Engineering, 416, Article 116336. https://doi.org/10.1016/j.cma.2023.116336
- Pretti, G., Coombs, W., Augarde, C., Sims, B., Puigvert, M., & Gutierrez, J. (2023). A conservation law consistent updated Lagrangian material point method for dynamic analysis. Journal of Computational Physics, 485, Article 112075. https://doi.org/10.1016/j.jcp.2023.112075