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material, binder, etc) and overall microstructure is controlled to vary spatially within the electrodes. These models will then be used to find a design that maximises the overall performance balance (energy
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, in which the local composition (active material, binder, etc) and overall microstructure is controlled to vary spatially within the electrodes. These models will then be used to find a design that
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( CONTENTed) study, and COVID-19 studies. We would like to hear from candidates with experience in conventional, tissue microstructural and functional MRI data analysis that are keen to continue output high
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enthusiastic researcher with experience in solid state materials chemistry, in particular synthesis and characterisation of metal oxides, to join the Attfield Research Group. This 36-month post will involve
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how interactions between excitons and other quasiparticles (e.g. phonons) impact the energy, formation and dissociation of excitons at finite temperatures. The main directions of this project will
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the existing joint team, currently consisting of postdocs, bioinformaticians, PhD candidates, and research assistants. You will be able to receive training in collaborating labs in order to benefit from
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equipment available in Bristol, from advanced thermal to microstructural analysis tools, and simulation methods (COMSOL, ANSYS); you have the opportunity collaborate within our 30-member team as well as with
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the following areas will be valued: logic in computer science, database theory, finite model theory, structural decomposition methods, term rewriting, and parameterized complexity theory. Travel funding will be
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micrometastases in cancer patients based on a novel MRI approach which combines multi-dimensional diffusion-relaxometry acquisitions, efficient data denoising and biophysical modelling of the tissue microstructure
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theory, finite model theory, structural decomposition methods, term rewriting, and parameterized complexity theory. Travel funding will be available to you, and you will have the opportunity to interact