W.J. Wadsworth scite author profile

We demonstrate a picosecond source of correlated photon pairs using a micro-structured fibre with zero dispersion around 715 nm wavelength. The fibre is pumped in the normal dispersion regime at ~708 nm and phase matching is satisfied for widely spaced parametric wavelengths. Here we generate up to 10;7 photon pairs per second in the fibre at wavelengths of 587 nm and 897 nm, while on collecting this light in single-mode-fibre-coupled Silicon avalanche diode photon counting detectors, we detect ~3.2x10;5 coincidences per second at pump power 0.5 mW.

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Experimental demonstration of graph-state quantum secret sharing

Bell

et al. 2014

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Quantum communication and computing offer many new opportunities for information processing in a connected world. Networks using quantum resources with tailor-made entanglement structures have been proposed for a variety of tasks, including distributing, sharing and processing information. Recently, a class of states known as graph states has emerged, providing versatile quantum resources for such networking tasks. Here we report an experimental demonstration of graph state-based quantum secret sharing-an important primitive for a quantum network with applications ranging from secure money transfer to multiparty quantum computation. We use an all-optical setup, encoding quantum information into photons representing a five-qubit graph state. We find that one can reliably encode, distribute and share quantum information amongst four parties, with various access structures based on the complex connectivity of the graph. Our results show that graph states are a promising approach for realising sophisticated multi-layered communication protocols in quantum networks.

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Experimental demonstration of a graph state quantum error-correction code

et al. 2014

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Scalable quantum computing and communication requires the protection of quantum information from the detrimental effects of decoherence and noise. Previous work tackling this problem has relied on the original circuit model for quantum computing. However, recently a family of entangled resources known as graph states has emerged as a versatile alternative for protecting quantum information. Depending on the graph's structure, errors can be detected and corrected in an efficient way using measurement-based techniques. Here we report an experimental demonstration of error correction using a graph state code. We use an all-optical setup to encode quantum information into photons representing a fourqubit graph state. We are able to reliably detect errors and correct against qubit loss. The graph we realize is setup independent, thus it could be employed in other physical settings. Our results show that graph state codes are a promising approach for achieving scalable quantum information processing.

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Quantum interference with photon pairs using two micro-structured fibres

et al. 2007

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Tapered fibers embedded in silica aerogel

et al. 2009

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W.J. Wadsworth

Photonic crystal fiber source of correlated photon pairs

Highly Birefringent Photonic Crystal Fibers

Ultrahigh Resolution Optical Coherence Tomography

High brightness single mode source of correlated photon pairs using a photonic crystal fiber

Experimental demonstration of graph-state quantum secret sharing

Experimental demonstration of a graph state quantum error-correction code

Quantum interference with photon pairs using two micro-structured fibres

Tapered fibers embedded in silica aerogel

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