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to improve mechanical performance in composite structures under extreme loads. Emphasis will be placed on the design of hybrid configurations capable of promoting controlled and progressive failure modes
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conditions. Polymer nanocomposites have shown great promise for sensing and actuation, but current drawbacks include limited mechanical robustness, environmental stability and sensitivity. This project aims
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combining physical models, sensor data, computational methods, and damage and fracture mechanics concepts to create a virtual replica of the composite tank, enabling predictive maintenance, lifetime
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compositions that optimise oxidation resistance, mechanical integrity, and compatibility with AM superalloys. Coatings will be fabricated and tested under high-velocity steam conditions, with degradation
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mechanisms, namely the remodelling of membrane lipids. Lipid remodelling is a process whereby bacteria selectively modify their membrane lipid composition in response to a particular environmental stimulus
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AI techniques for damage analysis in advanced composite materials due to high velocity impacts - PhD
We are pleased to announce a self-funded PhD opportunity for Quantitative assessment of damage in composite materials due to high velocity impacts using AI techniques. Composite materials, such as
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will investigate how microbiome composition influences the physiological performance of bivalves under environmental stress. Combining microbial community profiling with measures of animal physiology and
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roles in the uptake of sulphur from the soil, and emerging evidence suggests that sulphur metabolism influences the composition and function of plant microbiomes. However, this phenomenon has barely been
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. Predicting key physical and mechanical properties of marine sediments—such as shear strength, stiffness, and density—is central to designing offshore infrastructure, influencing foundations, anchors, cable
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. Predicting key physical and mechanical properties of marine sediments—such as shear strength, stiffness, and density—is central to designing offshore infrastructure, influencing foundations, anchors, cable