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For this innovative, interdisciplinary project, we are looking a (bio)physicist, with: • A successfully completed Ph.D. degree in biophysics or optical physics. • Practical experience and scientific
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simulations to model this process and, in conjunction with ongoing experimental studies, obtain design rules for the optimum crown ether, lithium counter-ion, and solvent, which will lead to enhancements in
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aerospace materials, hydrogen technologies, and sustainable aviation. Your research will directly support the UK's ambition to lead global decarbonisation efforts, shaping your future as a skilled innovator
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UK's ambition to lead global decarbonisation efforts while also developing your technical and innovation expertise, building a wider network across industry, academia and government, and advancing your
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, combustion, and process optimisation. The project is focussed on the development of novel interface capturing Computational Fluid Dynamics methods for simulating boiling in Nuclear Thermal Hydraulics
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for understanding natural magmatic processes on earth & other planetary bodies. Neutron diffraction is a powerful technique for studying the atomic scale structure of these materials, but the current technology to
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Supervisors: Dr Raj Pandya, Prof. Nicholas Hine, Prof. Reinhard Maurer While we as humans are used to seconds and hours, electrons and atoms in materials move a whole lot faster around a million
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consumption across a wide range of technologies, from aviation to renewable energy systems. The ability to reduce drag while maintaining or enhancing lift can lead to significant fuel savings, lower emissions
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with critical technical and professional skills, preparing them to lead the aviation sector’s transition toward sustainable hydrogen-based operations. While working on this exciting research project, you
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contain up to 100 non-hydrogen atoms, which makes the development of cost-effective and efficient synthetic pathways very challenging. Effective retrosynthetic design requires the ability to predict