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on aluminium and other light-alloy substrate systems, the developed tools will be widely deployable to any material system undergoing electromagnetic processing. The development of these theoretical tools and
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both the fundamental physics of electromagnetic materials and practical applications in 6G communications. The PhD is 4 years and funded by DSTL (Defence Science and Technology Laboratory), and you will
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multiscale metamaterials with sub-200 nm resolution. The research spans fundamental optical physics through to applications, and the student will develop skills in electromagnetic simulation, nanofabrication
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project, to train students, to interact with colleagues with different backgrounds (physics, engineering, chemistry) and from different disciplines (i.e., spectroscopy, electromagnetism, material science
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, thermal, electromagnetic or kinetic), are critical for the sustainable operation of wireless IoT devices and remote sensors. The world can reduce reliance on batteries and fossil-fuel-derived power if more
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modelling tools (CST or HFSS) - Fabricate and test for optimal electromagnetic performance, such as bandwidth, return loss, insertion loss and power-handling. - Develop and characterize new bonding/alignment
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these components inside the PCB and connect them internally, which not only saves space, but also easily confines the electromagnetic noise and manages the cooling of the system. Eventually, it will greatly reduce
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flexibility. Aim This PhD project aims to explore and optimise new electric machine topologies that go beyond conventional 2D radial designs. The candidate will investigate innovative electromagnetic
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radial designs. The candidate will investigate innovative electromagnetic configurations that leverage 3D flux paths to achieve higher power and torque density without compromising efficiency. Key