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Field
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of neutron-induced nuclear recoil backgrounds with multiple scatters in LZ. Measurement and simulation of muon-induced background in the LZ experiment. You will work alongside Prof Davide Costanzo and Prof Dan
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. The project is co-sponsored by Spirent Communications, a world leader in navigation and testing technology. Spirent will provide advanced simulation tools, expert support, and industry placements to help make
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out your project ideas; A one A4 page personal statement setting out why you are a suitable candidate (i.e.: your skills and experience); A copy of your degree certificate(s) and full transcript(s
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grid simulators such as Digsilent Power Factory or PSCAD. How to apply: Candidates should submit an expression of interest by sending a CV and supporting statement outlining their skills and interests in
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excite states in certain materials which can then be identified through inspection of the neutron energy spectra or emitted radiation. The project will initially involve simulation work using Monte-Carlo
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and heat transfer in geothermal systems under high-pressure and high-temperature conditions relevant to AGS. • Developing high-fidelity direct numerical simulation (DNS) models to map
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potentially be affected by the generated noise, establishing a feedback loop by these flow-acoustics interactions. In this study, we will extend our high-fidelity aeroacoustics simulation framework [3
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the opportunity for the PhD student to lead the development of innovative simulation tools that predict Litz wire behaviour across electrical, thermal, and mechanical domains. Supported by the MTC’s advanced wire
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) simulations towards mapping out the stability and selectivity of LCO structures for a range of conditions. The project will thus deliver fundamental understanding of the mechanisms that affect catalytic
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& environmental risk assessment. Numerical simulation techniques for hydrogeological systems. Advanced uncertainty quantification for robust modeling. Scientific communication, including publications & conference