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the interface between lattice field theory and particle physics, tailored around their scientific skills and ambitions, and will be leading the development, testing, and benchmarking of new pre-exascale ready
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, and a strong interest in applying advanced physical and computational methods to real-world challenges in energy and environmental technologies. The research will focus on the nano-architecture
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close collaboration with colleagues at Imperial College and partners in Germany and the USA, with the overall aim of exploring novel functional states in ferroelectric domain walls for future nano
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on novel nano-structured tungsten alloys for fusion (W-Cr https://doi.org/10.1016/j.apmt.2024.102430 and W-Ti-Fe https://doi.org/10.1016/j.apmt.2021.101014 ). This EngD/PhD project is set within the Fusion
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Department: Materials Title: Self assembled non-close packed quantum dot superlattices via high entropy approaches Application deadline: 17/06/2025 Research theme: Nano and Functional Materials How
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Overview: Air quality is a major public health issue worldwide. Two origins are identified for pollutant particles that emanate from passenger cars: those coming from the exhaust (linked
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model of particle physics can be tested, for example to help analyze experimental results from the LHC or the experiment to measure the properties of the muon at the Fermilab particle physics laboratory
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particles that may trigger early ignition. These phenomena can compromise engine safety, performance, and durability. In this project, you will explore how different oil formulations and engine parameters
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nature and industry are complex fluids, a heterogeneous mixture of at least two phases due to the presence of additives such as colloids, surfactants, and polymers. Examples include colloidal dye particles
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ambitious research team exploring quantum phenomena in large scale and complex systems, from high-temperature Bose-Einstein condensates to trapped solid-state particles in ultra-high vacuum. We combine