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to build molecular machines and new materials. The ability of their subcomponents to undergo large amplitude displacement, such as macrocycle shuttling in a rotaxane, make them ideal structures
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—where material is poured in bulk—3DCP constructs elements layer by layer via extrusion, introducing unique challenges related to interfacial bonding and structural performance. This PhD project aims
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A fully funded 3.5 years PhD position in developing software and computational tools for sustainable supramolecular materials design is available in the group of Assistant Professor Andrew Tarzia
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make them excellent candidates for topical wound healing treatment, the potential application of foldamers as biomaterials has not yet been explored. Moreover, 3D scaffolds obtained from supramolecular
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filled. Do you want to be at the heart of the clean energy revolution? This PhD project gives you the chance to design and build the novel materials that could make hydrogen-powered aircraft, electric cars
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, to support the experimental activity. The candidate will be joining a multidisciplinary team in a lab where we design, make and validate materials and structures. This PhD will expose the successful candidate
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of the clean energy revolution? This PhD project gives you the chance to design and build the novel materials that could make hydrogen-powered aircraft, electric cars and renewable energy systems safer
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presents an attractive strategy to mitigate climate change. For this purpose smart bio-inspired systems are particularly attractive, and we previously demonstrated self-assembled vesicle microreactors
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physics of electromagnetic materials and practical applications in 6G communications. The PhD is 4 years and funded by DSTL (Defence Science and Technology Laboratory), and you will undertake a mixture of
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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