Litcius/Paper detail

Protocols for long-distance quantum communication with single <sup>167</sup> Er ions

F Kimiaee Asadi, S C Wein, C Simon

2020Quantum Science and Technology29 citationsDOIOpen Access PDF

Abstract

Abstract We design a quantum repeater architecture using individual 167 Er ions doped into Y 2 SiO 5 crystal. This ion is a promising candidate for a repeater protocol because of its long hyperfine coherence time in addition to its ability to emit photons within the telecommunication wavelength range. To distribute entanglement over a long distance, we propose two different swapping gates between nearby ions using the exchange of virtual cavity photons and the electric dipole–dipole interaction. We analyze their expected performance, and discuss their strengths and weaknesses. Then, we show that a post-selection approach can be implemented to improve the gate fidelity of the virtual photon exchange scheme by monitoring cavity emission. Finally, we use our results for the swapping gates to estimate the end-to-end fidelity and distribution rate for the protocol.

Topics & Concepts

Quantum entanglementRepeater (horology)PhotonPhysicsQuantum channelCoherence (philosophical gambling strategy)Quantum information scienceQuantum networkIonOptoelectronicsComputer scienceCavity quantum electrodynamicsCoherence timeQuantum computerHyperfine structureQuantumHigh fidelityQuantum dotTeleportationVirtual particleQuantum metrologyQuantum key distributionQuantum sensorElectronic engineeringMultiplexingQuantum gateLogic gateAtomic physicsFidelityQuantum informationWavelengthBridging (networking)Quantum optics and atomic interactionsQuantum Information and CryptographyAtomic and Subatomic Physics Research