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specific microstructural arrangements, and how these microstructures dictate rheological and textural attributes of sustainable food materials. The research will be focused on plant-based proteins, as much
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out within the DFG Priority Programme “DaMic - Data-driven Alloy and Microstructure Design of Sustainable Structural Metals” (SPP 2489), in close collaboration with a research partner responsible for
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Vacancies PhD Position: Improved Temper Roll-Force Prediction Through Microstructural Modelling Key takeaways Steel is extensively used in sheet form across a wide range of applications. Two
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the rate of oxidation and corrosion, and the addition of other elements to stabilise the microstructure and increase the service life of the metal and thus reduce the need for component replacement
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greater stress. The understanding of the relation between the material microstructure – grain structure, grain orientations, defects – and the in-service performance of the wheel is limited at present
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to overcome tritium permeation, with the following objectives: Uncover the mechanisms driving hydrogen penetration. Evaluate the processes of different sites as a function of surface chemistry, microstructure
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development of high strength aluminium alloys designed to provide better performance compared with existing alloys. The properties of this alloy depend on careful control of the microstructure, in particular
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of steel the microstructures will change leading to unknown product properties. The aim of this project is to advance existing micromechanical models such as the well established Crystal Plasticity method
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) and hydrogen (H) – which can synergistically modify the microstructure development in materials [5]. This PhD will reveal the key irradiation-induced microstructure phenomenon in RAFM welds using in
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subsurface layers of components and even transform their microstructure, potentially introducing additional defects. Thus, assessment of these effects on structural reliability and durability of systems