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Field
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. First, it will develop high-fidelity CFD models of methane dispersion in representative environments, including idealised test cases and realistic geometries relevant to energy and environmental
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of time-varying photonic metamaterials. First-principles mathematical modeling of optic-wave physics in canonical geometries under space-time-varying polarization responses. Computer programming and
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algorithms suitable for multi-static and distributed geometries. Understanding the performance limits of such systems, including sensitivity to synchronisation errors, geometry, transmit time, and partial
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reduce the energy wastage in composites manufacturing. It enables components to be produced quickly without the use of an autoclave. For complex geometries, such as those used in wing spars of considerable
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to develop realistic physical models and to synthesise nanostructures that approximate as closely as possible the ideal geometries considered in the models, using the synthesis routes developed within the team
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explore how geometry, wettability, and fluid properties can be harnessed to achieve passive and energy-efficient liquid manipulation. The candidate will combine experiments and theoretical analysis
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is small but mighty. Working together with Leonardo UK towards immediate real-world applications in an operational environment, you’ll design and create intricate nanoscale geometries and combine
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high‑fidelity CFD across laminar, transitional, and turbulent regimes, including rotor and near‑wake benchmarks. Demonstrating scalability and generalisation across geometries, inflow conditions, and
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confined geometries - Advanced X-ray scattering methodologies - Integrated experimental and computational approaches 💡 Why join us? You’ll work in tightly integrated experimental–theoretical teams, gaining
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): Altermagnetic Spintronics Magnon transport in two dimensional systems: interplay between quantum geometry, topology and disorder Effective magnetization dynamics in coupled spintronic nano-oscillators Theoretical