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Field
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electrochemical flow technologies, such as redox flow batteries, multivalent metal ion batteries and/or capacitive deionisation. Such technologies are emerging as promising more-sustainable solutions for the global
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techniques for modelling and monitoring the infusion and curing process and this PhD will bring these elements together to form a digital twin of the process. This digital twin will be used to predict
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. These mobile genetic elements autonomously transfer between bacteria, disseminating resistance genes across microbial populations. Recent advances have demonstrated the potential of “counter-plasmids” that can
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niche factor, but less so in the bone marrow, where stem cells are known to reside in less oxygenated niches enabling them to maintain quiescence (doi: 10.1038/nature13034 ). This PhD will offer
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—where material is poured in bulk—3DCP constructs elements layer by layer via extrusion, introducing unique challenges related to interfacial bonding and structural performance. This PhD project aims
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. This steam can accelerate coating degradation and loss of protection, reducing component lifespan and increasing lifecycle costs. Therefore, coatings with enhanced environmental resistance in hot-steam
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Methods The stratified atmospheric boundary layer is a key component in high-impact weather and climate predictions. Forecast applications include: polar surface temperatures, the timing of thunderstorms
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on atomic scale, requiring the development and study of ever more realistic model systems. Single atom catalysts, where the catalytic site contains only a single metal atom supported on a heterogenous
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modelling framework to predict key thermal hydraulic parameters for boiling flows within complex geometries at high heat flux conditions, relevant to the engineering design of thermal management elements
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small elements of computational chemistry (electronic structure calculations) to help interpret experimental observations, supported by local and national supercomputing facilities. Entry Requirements