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Field
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of manufactured parts, particularly in terms of geometrical accuracy, microstructural control, and mechanical performance. This PhD project aims to develop a Multiphysics model and simulation to gain in-depth
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and next‑generation manufacturing, yet their performance is fundamentally limited by our inability to precisely control particle alignment and microstructure during fabrication. Existing methods—such as
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, the project will establish predictive frameworks capable of optimising process parameters, controlling microstructure evolution, and improving part quality in real time. Robotic platforms will be used
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the final weld. Microstructural simulation of grain sizes and morphology after solidification will be developed together with simulation of metallurgical phase transformations at microscale. Combining
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PhD student at ILL on Advanced Neutron Imaging for Defect Mapping in Repaired Aero-Engine Components
many conditions governing microstructural evolution and defect formation, yet the physics linking process conditions to three-dimensional defect distribution in engineering-scale geometries remains
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to close-to-magnet particle doses. The stability of a given austenite grain is governed by local microstructural parameters such as the local chemistry, grain size, orientation, the surrounding microstructure
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principles. The proposed project will investigate the development of TCRs by studying the impact of geometries and microstructures on the hydrodynamics of reactants in chemical and/or catalytic reactions and
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world. You will find more information about working at NTNU and the application process here. About the position Studies of phase formation, evolution of microstructure and casting defects in high
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microstructures on the hydrodynamics of reactants in chemical and/or catalytic reactions and solid handling processes. The successful PhD student will be co-supervised by Professor Kamelia Boodhoo and Dr. Fernando
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existing and newly designed titanium alloys. You will combine advanced 3D microstructure characterization using world-class facilities at The University of Manchester with forging simulation, both