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to deliver high-temperature, low-carbon energy for applications beyond electricity generation, and building on the UK’s extensive experience of gas-cooled reactor operation. HMG has selected
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contribute to scalable, rational design strategies for next-generation porous carbon materials and high-performance energy storage devices. Research Objectives and Methodology The project will combine
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, adaptability, and sustainability from the outset. By scientifically linking high-level performance objectives to system architecture and design decisions, this research aims to reduce costly late-stage redesign
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determined on a case-by-case basis. The start date is October 2026. We recommend that you apply early as the advert may be removed before the deadline. High-performance steel components for aerospace
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the large-scale deployment of hydrogen. Central to the performance of these systems is the ion-conducting membrane, which governs ionic transport, efficiency, durability, and operating conditions. Currently
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lower-cost offshore power architectures. The project will produce efficient, practical SWIPT systems with novel metamaterial devices, enhanced adaptability, and validated performance. Results will lead to
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to the development of compact, high‑performance imaging systems (i.e. for security and medical applications). Key Research Activities Fabrication and Characterisation of Silicon Pillars: Modelling and Simulation: THz
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highly efficient operation. TBCs are crucial to ensure the safe and high-performance operation of such critical parts under extreme temperatures and pressures; however, external contaminants (e.g. Calcium
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the wind/renewable energy training and research elements of the CDT programme. Funded by Siemens Energy and EPSRC, this 4 year this PhD studentship, at the University of Strathclyde is in the area of
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, faster and more energy efficient data processing and storage. However, the heat produced by modern data centres has already become a serious limitation to further increase their performance. At present