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Materials R26-06 Development of Advanced Ceramics and Composites R26-07 Development of Magnetic Materials with high functionality by Data-Driven method R26-08 Welding and Joining R26-09 Microstructure
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that link between processes, microstructures and function. Applicants should have, or expect to achieve, at least a 2.1 honours degree or a master’s (or international equivalent) in a relevant science or
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AMMETIS[1] (AI-assisted Simulations of Microstructure driven Mechanical properties from high Throughput and multiscale analysIS), in the framework of PEPR DIADEM[2] , which aims to develop an advanced
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] (AI-assisted Simulations of Microstructure driven MEchanical properties from high Throughput and multiscale analysIS), in the framework of PEPR DIADEM[2] , which aims to develop an advanced
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testing of contemporary and vintage runner materials will be performed to assess the influence of ageing, microstructural variability and service history. A purpose-designed model specimen will be developed
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of: Perform advanced microstructural and topological analysis of natural fibres using 3D imaging and image‑processing tools. Design and refine routes to isolate and tailor lignin fractions derived from
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, structural testing of the column under static and impact loadings, and characterisation of impact tested tubes to assess microstructural damage. The project addresses critical gaps in current design practices
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, spectroscopic signatures, microstructural images, processing conditions, and macroscale performance will be used for the optimization of materials. The candidate will collaborate extensively with in
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-assisted Simulations of Microstructure driven Mechanical properties from high Throughput and multiscale analysIS), in the framework of PEPR DIADEM[2] , which aims to develop an advanced characterization
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, regarding microstructure design, colloids and soft matter, preferably with an international scope and applied approach. Proven expertise in food microstructure and functionalisation techniques for alternative