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Start Date: 1th October 2026 Application deadline: 26th March 2026 Introduction: This PhD project in Thermo-structural design of hypersonic vehicles under extreme material nonlinearity will be
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About the Project An exciting PhD project on the effects of heat transfer of transitional compressible boundary layers will be carried out under the UK Hypersonics Doctoral Network, which has been supported by the Ministry of Defence and EPSRC for building the necessary expertise to develop...
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About the Project An exciting PhD project on the effects of heat transfer of transitional compressible boundary layers will be carried out under the UK Hypersonics Doctoral Network, which has been supported by the Ministry of Defence and EPSRC for building the necessary expertise to develop...
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and quantum cybersecurity applications? Can we scale-up multiphoton platforms by using integrated optics, quantum-dot single-photon sources and customized two-dimensional nonlinear materials
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the complex multiscale nonlinear interactions at the origin of such extreme events. In this project, you will develop machine learning-based reduced-order models which can accurately forecast
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Application deadline: 30/06/2026 Research theme: Applied Mathematics, Continuum Mechanics, Nonlinear PDEs How to apply: https://uom.link/pgr-apply-2425 UK only due to funding restrictions. The
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computational techniques. In particular, we are looking for curious, enthusiastic and hard-working candidates with the following expertise: -- strong understanding of concepts in nonlinear waves and fluid
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applications, ensuring system stability across a wide range of nonlinear loads and operating conditions. Aim You will have the opportunity to research and implement innovative approaches to ensure stability and
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to break that barrier by developing a groundbreaking MEMS-based neuromorphic platform that physically implements Reservoir Computing (RC), a bio-inspired approach using nonlinear dynamics for fast, efficient
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behaviour, bridging the gap between molecular simulations and rheology. This interdisciplinary project will provide valuable insights into micellar dynamics, surfactant self-assembly, and nonlinear rheology