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thermal resistance – potentially modifying the coupled electro-mechanical-fluid loading and causing fatigue and early failure. This PhD project will investigate how biofouling affects the hydrodynamic
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to mineral dissolution followed by the precipitation of secondary minerals. From a fluid dynamics perspective, the newly formed solids can be regarded as particles suspended within the pore-scale flow
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Due to unique properties of supercritical CO2 (sCO2), power generation systems using sCO2 as working fluid have many advantages over their counterparts, such as gas turbines and steam turbine power
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developed during this work will deepen our understanding of nonlinear wave phenomena in fluid mechanics and contribute to the broader theory of interfacial flows. This PhD project is in a competition for a
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material properties affect dimensional accuracy and aerodynamic behaviour, ultimately improving the reliability of aerodynamic testing. The project combines additive manufacturing, data analytics and fluid
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. From a fluid dynamics perspective, the newly formed solids can be regarded as particles suspended within the pore-scale flow. The primary objective of this project is to investigate the transport
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and hard biofouling – marine organisms that increase drag, weight and thermal resistance – potentially modifying the coupled electro-mechanical-fluid loading and causing fatigue and early failure
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industrial partner, this project aims to develop a novel modelling and analysis approach to address the mathematical and technical challenges of the fluid-structure interaction (FSI) mechanisms globally
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potential of this technology. This is exactly what this PhD project is about. Depending on your interests and skills, you will be working on one or more of the following research challenges: Using fluid
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Home fee status. Applications from non-UK candidates will not be considered. 1st or 2:1 academic qualification in Engineering or Physical Sciences or a related discipline, with expertise in fluid