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ultrafast laser pulses on femtosecond timescales. Combining nanofabrication, electromagnetic simulation, and pump–probe laser measurements, the project will explore how 3D geometry, and different materials
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faults in simulation, you'll reduce the need for wasteful physical trial-and-error testing, leading to lower energy consumption and material waste. The project also supports the reliability of automated
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-efficient research that prevents fatigue failures has pushed towards integrated computational materials engineering approaches that improve competitiveness. These approaches rely on physics-based models
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materials. You would work as part of a larger team spread across a number of sites including Warwick and KCL London, who will provide different opportunities for you to develop the research. You would be also
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simulations and finite element analysis, with high-heat flux electron beam experiments. The research will simulate and replicate steady, cyclic, and transient thermal loads to better understand PFM behaviour
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experiment, theory, and numerical simulations in the department of physics at the University of Exeter. The research question is how to effectively shape electromagnetic radiation when the wavelength reaches
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potential. Our research focuses on Materials physics; Quantum technology; Soft & living matter; and Advanced energy solutions. Topics extend from fundamental research to important applications. We educate
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at ever-increasing frequencies, there is a growing need for new high-performance electromagnetic simulation technologies to enable rapid design and optimisation in both research and industry. Towards
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an integrated zero-emission system and setting a new benchmark for sustainable innovation. This project will upcycle underutilised olive mill waste (OMW) into high-value products, including plant
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involve the following technical tasks: To develop a bespoke simulation environment for forming doubly-curved shell structures from recycled, short-fibre composites To propagate uncertainty in material