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Field
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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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the coupling of these collective excitations with Cooper pairs in superconductors and electromagnetic fields in cavity QED setups. The project aims to understand how such interactions influence quantum transport
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information from a multitude of cosmic messengers, including electromagnetic radiation, neutrinos and gravitational waves, has led to several groundbreaking discoveries during the last few years with
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moisture, and CO₂ levels. The proposed research will design an autonomous SPS node integrating bespoke energy harvesters (electromagnetic or piezoelectric) with sensors. The final deliverable will be a
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the coupling of these collective excitations with Cooper pairs in superconductors and electromagnetic fields in cavity QED setups. The project aims to understand how such interactions influence quantum transport
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or equivalent). The PhD candidate is expected to have keen interest on Quantum Mechanics, Quantum Optics and Electromagnetism and good mathematical skills. The project will take place in
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Electromagnetism and good mathematical skills. The project will take place in the Nanophotonics group of Prof Angela Demetriadou (https://www.birmingham.ac.uk/staff/profiles/physics/demetriadou-angela.aspx ), which
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of dark matter production through axion domain walls; • Study of scalar field interaction phenomena; • Analytical and numerical development of models for gravitational and electromagnetic signals
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/Python and signals processing Understanding of electromagnetics Experience with CAD and mechanical design How to apply: Interested candidates should submit a full formal application, guidance and the