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Quantum Repeater Node Demonstrating Unconditionally Secure Key Distribution

Stefan Langenfeld, Philip Thomas, Olivier Morin, Gerhard Rempe

2021Physical Review Letters80 citationsDOIOpen Access PDF

Abstract

Long-distance quantum communication requires quantum repeaters to overcome photon loss in optical fibers. Here we demonstrate a repeater node with two memory atoms in an optical cavity. Both atoms are individually and repeatedly entangled with photons that are distributed until each communication partner has independently received one of them. An atomic Bell-state measurement followed by classical communication serves to establish a key. We demonstrate scaling advantage of the key rate, increase the effective attenuation length by a factor of 2, and beat the error-rate threshold of 11% for unconditionally secure communication, the corner stones for repeater-based quantum networks.

Topics & Concepts

Quantum key distributionRepeater (horology)Quantum networkComputer scienceQuantum information sciencePhotonSecure communicationPhysicsNode (physics)QuantumOptical communicationQuantum mechanicsQuantum entanglementTelecommunicationsOpticsComputer networkEncoding (memory)EncryptionArtificial intelligenceQuantum Information and CryptographyQuantum optics and atomic interactionsQuantum Mechanics and Applications
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