Deterministic delivery of remote entanglement on a quantum network

Large-scale quantum networks promise to enable secure communication, distributed quantum computing, enhanced sensing and fundamental tests of quantum mechanics through the distribution of entanglement across nodes. Moving beyond current two-node networks requires the rate of entanglement generation...

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Veröffentlicht in:	arXiv.org 2018-01
Hauptverfasser:	Humphreys, Peter C, Kalb, Norbert, Morits, Jaco P J, Schouten, Raymond N, Vermeulen, Raymond F L, Twitchen, Daniel J, Markham, Matthew, Hanson, Ronald
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Sprache:	eng
Schlagworte:	Decoupling Diamonds Entangled states Networks Nodes Physics - Quantum Physics Protocol (computers) Quantum computing Quantum entanglement Quantum mechanics Quantum theory Qubits (quantum computing)
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creator	Humphreys, Peter C Kalb, Norbert Morits, Jaco P J Schouten, Raymond N Vermeulen, Raymond F L Twitchen, Daniel J Markham, Matthew Hanson, Ronald
description	Large-scale quantum networks promise to enable secure communication, distributed quantum computing, enhanced sensing and fundamental tests of quantum mechanics through the distribution of entanglement across nodes. Moving beyond current two-node networks requires the rate of entanglement generation between nodes to exceed their decoherence rates. Beyond this critical threshold, intrinsically probabilistic entangling protocols can be subsumed into a powerful building block that deterministically provides remote entangled links at pre-specified times. Here we surpass this threshold using diamond spin qubit nodes separated by 2 metres. We realise a fully heralded single-photon entanglement protocol that achieves entangling rates up to 39 Hz, three orders of magnitude higher than previously demonstrated two-photon protocols on this platform. At the same time, we suppress the decoherence rate of remote entangled states to 5 Hz by dynamical decoupling. By combining these results with efficient charge-state control and mitigation of spectral diffusion, we are able to deterministically deliver a fresh remote state with average entanglement fidelity exceeding 0.5 at every clock cycle of $\sim$100 ms without any pre- or post-selection. These results demonstrate a key building block for extended quantum networks and open the door to entanglement distribution across multiple remote nodes.
doi_str_mv	10.48550/arxiv.1712.07567
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subjects	Decoupling Diamonds Entangled states Networks Nodes Physics - Quantum Physics Protocol (computers) Quantum computing Quantum entanglement Quantum mechanics Quantum theory Qubits (quantum computing)
title	Deterministic delivery of remote entanglement on a quantum network
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