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This PhD project is at the intersection of electromagnetism, numerical methods, and high-performance parallel computing, with application towards the design and optimisation of integrated circuits
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wireless communication systems. The PhD student will carry out specifically the following initial tasks: implementation, and calibration of the microscopy system; electromagnetic modelling of the near-field
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, to interact with colleagues with different backgrounds (physics and engineering) and from different disciplines (i.e., electromagnetism, RF communications, material science). Details of the project will be
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with first class honours or equivalent). The PhD candidate is expected to have a keen interest in electromagnetism and communication systems. University of Birmingham is committed to promote diversity
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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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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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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 undertake a mixture of
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. Plasmonic cavities, with their ability to confine light at subwavelength scales, enable strong coupling between electromagnetic fields and molecular excitations [1-6]. This coupling can lead to the generation
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This PhD project investigates ultrafast optical switching in plasmonic nanogaps, leveraging their exceptional ability to confine electromagnetic fields into sub-nanometer volumes [1-6]. Plasmonic
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interactions. The research will focus on designing plasmonic platforms to trap proteins non-invasively in aqueous environments, using the intense electromagnetic fields within nanogaps. Surface-enhanced Raman