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catalysts. This EPSRC-funded project leverages cutting-edge X-ray spectroscopy to unlock how alkali elements can be harnessed to create powerful heterogeneous catalysts for CO₂ and hydrogen technologies. By
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simple identification of nuclear material even when the typical signatures of the materials may be unavailable. X-ray imaging is commonly used to image concealed objects but x-rays are attenuated in
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-billionths of a second (femtosecond). X-ray free-electron lasers (XFEL) are a powerful tool to watch material dynamics on these timescales but how to design and interpret XFEL experiments remains challenging
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disability studies with environmental humanities (cf. e.g. Ray and Sibara [eds] 2017) to outline a series of case studies from across history, literature and/or the arts; it is flexible in terms of which
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cobalt-free cathodes. The project can involve aspects of materials synthesis, x-ray diffraction and crystallography, scientific software development and machine-learning enhanced analysis depending
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will provide training in nanomaterials synthesis, soft matter physics, X-ray scattering, and data-driven experimental design. The student will gain expertise in an emerging area of colloidal science
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. In this project, you’ll have the opportunity to be trained and become a proficient user of a range of advanced experimental techniques. For instance, you’ll learn how to use in-situ X-ray Computed
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ways, mechanical properties test (such as tensile test, etc.) and some highly advanced microstructural characterisation such as SEM (Scanning electron microscope), XRD (X-ray diffraction) and TEM
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the design of fundamentally new alloys by computational methods; production through arc melting, powder metallurgy or additive manufacturing; characterisation using advanced electron microscopy and x-ray
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the design of fundamentally new alloys by computational methods; production through arc melting, powder metallurgy or additive manufacturing; characterisation using advanced electron microscopy and x-ray