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optical lattices - Dissipative many-body dynamics, including measurement and feedback, and non-markovian dynamics with applications to quantum transport. The successful candidate will conduct
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optical characterisation of nano- and quantum photonic devices, integrating quantum light emitters. They will work on a research project focused on the investigation of the optical properties
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process for funding, there are a maximum of nine awards available. Project Details Two-dimensional (2D) van der Waals (vdW) materials feature exotic electrical, magnetic, optical, and structural properties
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for not only making conventional optical components more compact but also for bringing new integrated functionalities that we hope to exploit in quantum technologies. While metamaterials stretch
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Council). Project Details Non-linear quantum optomechanics Achieving partial control of 127 quantum bits (qubits) [1] shed light on the progress in the field of quantum computing, but also on the critical
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commercial skills. Optical fibres can transport light over long distances with very low loss. However, transporting quantum bits (qubits) using photons suffers from the interaction of the qubits with the glass
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narrowband and tunable scientific lasers, and have experience in atomic physics, quantum optics or laser cooling and trapping. The post holder is expected to be able to work effectively both independently and
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facility focussed on the production of superconducting quantum electronic devices for research and industry. It is located on the main Egham campus of Royal Holloway, University of London and is part of
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transitions that can be probed with optical and microwave techniques [1,2], and thanks to a spatial extension on the scale of the atomic lattice, they can provide an exquisite probe of their local environment
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overcome this limitation, providing ps-scale pulses with strong electric fields entering the GV/m regime, driving new research in areas such as ultrafast magnetism, quantum optics, superconductivity and