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of ultracold atoms. - Develop and expand collaborations with theoretical groups and well development of numerical toolbox to simulate magnetic atom is optical lattices in line with strategic objectives. - Mentor
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temporal laser pulse shaping, together with accurate modelling of the underlying beam physics, is therefore a key prerequisite for fully exploiting the XFEL's potential. Dedicated numerical and experimental
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Posting Details Student Title Classification Information Quick Link https://chapman.peopleadmin.com/postings/39133 Job Number SE179024 Position Information Department or Unit Name Fowler School
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be analyzed in terms of the generated radiation stresses. The project will combine analytical modeling, numerical simulations (FEM), and experimental campaigns, in collaboration with physico-chemist
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plausible deployment pathways. Numerical simulations will first be conducted in isolation, focusing on OAE alone, and will then be extended (in collaboration with other PhD students and postdocs) to combined
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theoretical models and numerical tools (master equations, quantum trajectory simulations) to investigate coupling regimes, dynamical phase transitions, and the effects of collective dissipation on coherence and
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flows in industrial bioreactors. It aims to use new experimental techniques as well as advanced numerical approaches to improve CFD simulation tools and their application for the scale-up of bioreactors
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of the β-decay rate of isotopes immersed in an ECR plasma. The experiment consists of a numerical modelling of plasma, including electron and ion dynamics, and the consequent estimation of the lifetime
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(or equivalent) in theoretical physics, applied mathematics, or related disciplines; A strong interest in non-equilibrium statistical physics, cross-scale physics of living systems, and numerical simulations
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. • Advanced High Performance Computing Cluster: Run advanced simulations and analyze them using numerical tools. • Global Exposure: Contribute to publications in leading journals and attend international