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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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motivated, enthusiastic person, with passion for research in topics such as quantum networks, entanglement distribution, quantum key distribution, advanced optical network for quantum technologies and
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where long-term data security is needed. Quantum key distribution (QKD) is a technique that would provide the required level of data security but has so far been limited to fixed optical implementations
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Quantum Photonics group, based in the Nanoscience Centre at the University of Cambridge, a newly founded research group that works on simulation, nanofabrication and optical characterisation of nano- and
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highly motivated, enthusiastic person, with passion for research in topics such as quantum networks, entanglement distribution, quantum key distribution, advanced optical network for quantum technologies
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semiconductor processes [2]. A QM is a device that couples classical memristive behaviour with quantum coherence [3]. Several approaches to realise QMs have been envisaged and more recently a quantum optical
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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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Funding providers: EPSRC Quantum Technologies DTP Subject areas: Experimental Physics, Lasers, Optics, Semiconductors Project start date: 1 October 2024 (Enrolment open from mid-September) Project
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electrical transport, integration of spin/electrical/optical signals and the formation of bound Majorana states for topological quantum computation. [1,2] We have recently developed the ability to grow highly