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Qualification: Doctor of Philosophy in Engineering (PhD) Eligibility: UK Students, EU Students, International Students Award value: Home fees and tax-free stipend - See advert for details Project
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This PhD project aims to achieve a breakthrough in thermal efficiency (>50%) for dual-piston Free-Piston Engine Generators (FPEGs). The research will pioneer a novel, integrated methodology
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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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approaches for designing new supramolecular materials. Using, for example, a mixture of classical and quantum mechanics simulations, cheminformatics and coarse-grained simulations, we will uncover the design
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applicant must have (or be close to obtaining) a relevant PhD in Fluid Mechanics from an Engineering, Mathematics or Physics Department, a strong background in theoretical and computational fluid mechanics
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Are you ready to push the boundaries of engineering innovation and accelerate the world’s transition to carbon-neutral energy systems? Join the Thermofluids Group in the School of Mechanical
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-generation mechanical seals for high-pressure hydrogen systems—key to renewable energy. Work with Industry Leaders: Collaborate with John Crane, a $1B global technology company driving sealing innovation. Gain
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into viral mechanisms, supporting applications in diagnostics, biotechnology, and phage research. The student will join a vibrant research environment in the School of Computer Science and Engineering, working
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thin dielectric layers, high localised electrical field stress, and the difficulty of ensuring consistent manufacturing quality. Furthermore, the fundamental understanding of its ageing mechanisms under
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) status, ensuring you’re recognised for your professional expertise. Entry Requirements: A first-class or strong 2:1 degree in a relevant science or engineering subject such as Mechanical Engineering