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Field
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at an atomic-resolution level, uncovering causal links of their microstructure with optoelectronic properties and stability. These advances will be accomplished through a co-ordinated and well-interlinked
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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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materials, the design and optimization of catalytic reactors, the study of reaction kinetics, and the detailed microstructural and physicochemical characterization of catalysts. The primary objective is to
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tailoring their microstructure and to develop a direct link as well as a closed loop between processing and fabrication of materials on one hand, and material characterisation and simulation-theoretical
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controlled by tailoring their microstructure and to develop a direct link as well as a closed loop between processing and fabrication of materials on one hand, and material characterisation and simulation
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, microstructure, mechanical properties, and injectability. Conduct biological assessment, including cell viability, phenotype, ECM deposition, and immunomodulatory profiling in vitro. Contribute
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uniaxial creep tests (tension, compression) and comparing the results Characterization of the microstructure–property relationship using optical microscopy, SEM and EBSD Correlation of microstructure and
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microstructural characterisation. You will also work closely with modelling specialists to connect what you observe in the lab to behaviour across multiple length scales, contributing to a powerful design framework
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will be used: NMR, methods for the measurement of fresh mixes’ rheology, characterization techniques for hardened properties (microstructure and mechanical performance) and further techniques useful
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simulation software modelling the dynamic behavior of dislocations (DDD) in 3 dimensions, coupled with a spectral solver based on FFT. The procedures must analyze the simulated 3D microstructures to compare