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scientific computing, to name a few. Modern LC applications rely heavily on accurate and efficient mathematical modelling of confined LC systems. Typical questions are - can we theoretically predict physically
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This exciting project aims to experimentally and theoretically investigate the fundamental nucleation and heat transfer mechanisms in high-pressure flow boiling, in particular Critical Heat Flux
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of Astronomy, Department of Applied Mathematics and Theoretical Physics, Yusuf Hamied Department of Chemistry, Department of Biochemistry, Department of Earth Sciences, Department of Zoology, Department
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with experimental and theoretical scientists from chemistry and physics. For relevant papers by our team, see: Physical Review Letters 133, 1, 013201 (2024); Nature 636, 8043, 603-608 (2024); Dalton
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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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desirable as would experience integrating behavioural, phenomenological and neuroimaging datasets with theoretical implications. Diversity Committed to equality and valuing diversity Application Process You
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and emerging applications, such as multi-domain autonomy and aerial mobility. With rising risks to PNT systems from interference, spoofing, and cyber-physical attacks, unified, security-aware integrity
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infrastructure. However, the increasing application requirements and rising threats from intentional interferences, spoofing, and cyber-physical attacks expose vulnerabilities in conventional GNSS-centric systems
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. Investigating if and how classical systems can offer trustworthy, scalable, and efficient validation for quantum technologies is the crucial theoretical and practical challenge we aim to address. Our unique
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these sectors, design customized technological solutions using advanced sensing and analytics, and validate these innovations through real-world implementation. The project will bridge the gap between theoretical