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and knowledgeable in the areas of stress analysis (including the Finite Element Method), material characterisation (particularly flow stress determination and modelling), mechanical testing methods
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by using commercial software such as Ansys, Abaqus, SolidWorks, etc. Experience in computational fluid dynamics (CFD) modelling or finite element (FE) modelling; Fundamental knowledge in fluid
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experience in use of Finite element analysis and its application, familiarity with electric machines Contact: h.ghadbeigi@sheffield.ac.uk, m.i.boulis@sheffield.ac.uk Keywords: Manufacturing, Sheet forming
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finite element analysis Structures and construction material lab testing You will have gained this experience and expertise through engagement in practice, or through your substantial proven teaching and
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. These findings will inform a new generation of Finite Element computational models that seek to include the complex behaviour of rocks into volcano deformation models. You will join and work with Dr Craig Magee
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such as finite element analysis, computational fluid dynamics or tribology. Applicants with an interest in thin film lubrication, wear modelling, fluid-structure interaction and/or the applications on human
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during magma emplacement. These findings will inform a new generation of Finite Element computational models that seek to include the complex behaviour of rocks into volcano deformation models. You will
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of developing novel computational frameworks that seamlessly integrate machine learning techniques with established methods in computational mechanics, such as the Phase-field Finite Element Methods. Potential
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techniques — as well as theoretical and computational techniques that may include finite element methods, crystal plasticity theory, damage theory, molecular dynamics and advanced multiscale modelling methods
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code based on Modified Newtonian aerodynamics and a coupled, nonlinear thermo-structural finite element solver. Supervisors: Professor Matthew Santer, Dr. Paul Bruce. Learning opportunities: You will