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) provide a good insight into our research in these areas. Whilst most research until now has concentrated on droplets of simple fluids (e.g. water), in some of the most important industrial applications (e.g
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Supervisors: Supervisors: Dr. Radu Cimpeanu (Maths), Dr. Ellen Luckins (Maths) Summary: Interfacial fluid flows around obstacles and through porous materials are key to numerous applications
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. Such codes are also needed now to interpret existing experimental data. Warwick has developed a dedicated fluid code for this work but it is missing some key physics packages. The code needs to include
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to challenge current state-of-the-art in computational modelling of heterogeneous, ‘real world’ systems across a range of research themes such as nanoscale devices, new catalysts, superalloys, smart fluids
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computational modelling of heterogeneous, ‘real world’ systems across a range of research themes such as nanoscale devices, new catalysts, superalloys, smart fluids, space plasmas etc. They have recently been
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modelling of heterogeneous, ‘real world’ systems across a range of research themes such as nanoscale devices, new catalysts, superalloys, smart fluids, space plasmas etc. They have recently been awarded £11m
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world’ systems across a range of research themes such as nanoscale devices, new catalysts, superalloys, smart fluids, space plasmas etc. They have recently been awarded £11m to train PhD cohorts in
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catalysts, superalloys, smart fluids, space plasmas etc. They have recently been awarded £11m to train PhD cohorts in computation modelling. HetSys is built around a closely knit, highly collaborative team