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for ceramic armour materials, at the lowest possible economic cost, is therefore important. Ballistic resistance in ceramics is closely related to microstructure and grain size. In general, increases in
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and dynamic research team working across aerospace, automotive, energy, defence, and biomedical sectors. The groups expertise includes alloy design, microstructure-property relationships, phase
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optimization, and the interplay between microstructure properties and the LPBF technique. Key aspects of the project will include the: (1) Development of novel and next generation functional materials for LPBF
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selected candidates to give a lecture to the academic community of the Faculty. Apply here Qualifications Knowledge and experience in microstructure characterization methods, including the operation and data
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of ceramic disks Piezoelectric characterization of cold-sintered ceramic disk Explore the mechanical properties of cold-sintered ceramic disks using biaxial test methods Explore microstructural
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affected by tectonic events, overprinting the primary magmatic processes. Complicated geological histories result in modification of the mineral chemistry and rock microstructure. The study area, Bjerkreim
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from the physics and mechanics of the underlying multi-phase microstructure. An integrated numerical-experimental approach is generally adopted for this goal. A state-of-the-art computing infrastructure
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with respect to R&D work related to TS coatings. The core focus of the group's research revolves around unravelling the fundamental correlations between process parameters, coating microstructure, and
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vulnerable to the use of recycled material, with possibly uncontrolled or variable content. Accordingly, this research project aims to establish predictive insights between microstructures contaminated with
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research team working across aerospace, automotive, energy, defence, and biomedical sectors. The group's expertise includes alloy design, microstructure-property relationships, phase transformations, and