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Field
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applied physics other related disciplines. Demonstrated knowledge in at least one of the following areas: porous media flow computational fluid dynamics (CFD) pore-network modelling lattice Boltzmann method
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flow phenomena. The goal is to integrate theoretical and experimental fluid dynamics with modern computational tools to analyze and predict multiphase flow behavior. The project also involves applying
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overcomes the geographic limitations of conventional systems, enabling global scalability and accessibility. Using advanced computational fluid dynamics (CFD) approaches, the project is aimed at advancing
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numerical, utilizing computational fluid dynamics (CFD) to create high-resolution simulations. These simulations will capture the intricate turbulent dynamics of the flows, providing a detailed picture of
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a first or second-class UK honours degree (or equivalent) in aerospace/mechanical engineering, physics, or a related field. Experience in numerical fluid dynamics is helpful but not essential
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processes around fixed bottom offshore wind foundations, (2) Computational fluid dynamics modelling based on Lattice Boltzmann (LB) framework to simulate sediment transport surrounding offshore infrastructure
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interactions involved remains a challenge. Experimental methods are often limited by the fast timescales and small length scales of these interactions, while conventional computational fluid dynamics (CFD
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experience in computational modelling. It will involve the use of open-source computational fluid dynamics codes, with turbulence modelling and porous media approaches. It will also require the development
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research spectrum covers a unique range. Institute of Coastal Ocean Dynamics The Institute of Coastal Ocean Dynamics at the Hereon develops innovative technologies, investigates the physical and
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, focusing on performance, operability, and dynamic behaviour (e.g. water hammer effects). Working closely with Rolls-Royce, your research will develop and validate models using real-world industrial data