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: Research excellence. Ideal candidates will be published research in at least one of the following areas: adaptive finite element methods, discontinuous Galerkin methods, multigrid methods, domain
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structural materials (both metals and ceramics), computational solid mechanics, and thermohydraulics. The successful candidate will develop automated frameworks for finite element analysis of high temperature
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-equilibrium and finite size effects in magnetic materials, metal hydrides and soft matter. Samples are synthesised and studied with e.g. optical methods and transport measurements in-house. These
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simulations based on Smoothed Particle Hydrodynamics (SPH) or Finite Element Method (FEM), which require significant computational resources and expert knowledge. These traditional methods lead to prolonged
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finite element simulations Familiarity with the basic structure-property relations of high-temperature ceramics Expertise in microscopy and image reconstruction or segmentation methods Excellent written
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part of a degree program. In particular, knowledge about finite-element analysis is an absolute must . Familiarity with iterative solvers , preconditioners , multigrid methods , and mixed-precision
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., Multiphysics finite element analysis, Matlab, Labview etc.) cleanroom experience, and characterization of electronic devices are required. Further, knowledge of system level integration and haptics feedback in