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using both mono-material and blended fibre systems to meet the mechanical, chemical, and thermal demands of diverse industrial processes. While mono-material felts offer simplified recyclability, blended
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materials science. Applicants should hold a first-class (or equivalent) degree in a relevant engineering or science discipline (upper second class may be considered depending on the bachelor's/master's
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structures. This highly interdisciplinary project combines mechanical engineering, materials science, and control systems, and will require both numerical simulation and experimental validation. The outcomes
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-efficient research that prevents fatigue failures has pushed towards integrated computational materials engineering approaches that improve competitiveness. These approaches rely on physics-based models
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the Department of Materials Science and Metallurgy, University of Cambridge and the new AstraZeneca Discovery Centre at Cambridge. Closing date for applications: 21 November 2025 with interviews shortly afterwards
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not contribute to the increase in Anti-Microbial Resistance (AMR). The project will have a key focus on exploiting and developing chemistry to obtain materials at the hundreds of gram scale. because it
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not contribute to the increase in Anti-Microbial Resistance (AMR). The project will have a key focus on exploiting and developing chemistry to obtain materials at the hundreds of gram scale. because it
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an integrated zero-emission system and setting a new benchmark for sustainable innovation. This project will upcycle underutilised olive mill waste (OMW) into high-value products, including plant
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building blocks to elicit properties far beyond simple averaging over the component materials involved, instead giving exciting opportunities for new functionalities that are not found in natural materials
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potential. Our research focuses on Materials physics; Quantum technology; Soft & living matter; and Advanced energy solutions. Topics extend from fundamental research to important applications. We educate