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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
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the effect of thermal tempering on thin film microstructure while focusing on the evolution of mechanical properties and adhesion. Different thin film stack architectures will be synthetized by PVD techniques
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will focus on understanding structure–property relationships in hard carbon, with particular emphasis on microstructure, surface chemistry, and solid electrolyte interphase formation. In parallel
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include very high temperature stability, high mechanical stability and longevity, excellent chemical resistance, and tuneable microstructure. Combined with the design freedom of 3D printing, we have the
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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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. Elements such as copper and tin, which are the focus of this project, enrich at grain boundaries during thermo-mechanical processes used to achieve the desired steel microstructure. In this project, you will
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characterization of advanced materials with unique properties for innovative engineering applications. We develop materials with precisely controlled nanoscale microstructures, enabling enhanced mechanical, magnetic
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comprise the metallurgical synthesis of metallic glasses and their microstructural characterization, the implementation of strategies for electrochemical surface modifications and advanced chemical coating
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through microstructural characterization and comparing experimental observations with thermodynamic model predictions. Publishing your findings in peer-reviewed international journals and presenting
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wave attenuation for discriminating microstructural effects of thermal damage from moisture conditions in concrete, NDT & E International, 156, 2025. https://doi.org/10.1016/j.ndteint.2025.103473 [2] Y