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Topological phases of matter have reshaped how we think about quantum systems. Unlike conventional phases (such as solids, liquids, or magnets), which are characterized by local order, topological
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of their parts. Replacing conventional radar oscillators with their Quantum alternatives is possible and can drastically increase the hardware sensitivity of distributed radar systems. They introduce new
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exchange energy at such rapid rate that they blend together to form hybrid states at room temperature (strong coupling regime). We recently shown that one can control the quantum state and interaction
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tools using cavity quantum electrodynamic (QED) descriptions, to model and understand this complex interaction between plasmons in small gaps and the vibrational behaviour of molecules. The student will
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holder of the Athena SWAN Silver Award. Both initiatives recognise the School’s commitment to promote diversity and equality, and to encourage better practice for all members of the community, whilst also
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Join the University of Birmingham for groundbreaking PhD research to make 6G possible! Future radio communication systems (6G and beyond) will use frequencies above 100 GHz to achieve bit rates
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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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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