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Experimental wavelength-multiplexed entanglement-based quantum cryptography

Johannes Pseiner, Lukas Achatz, Lukas Bulla, Martin Bohmann, Rupert Ursin

2021Quantum Science and Technology39 citationsDOIOpen Access PDF

Abstract

Abstract In state-of-the-art quantum key distribution systems, the main limiting factor in increasing the key generation rate is the timing resolution in detecting photons. Here, we present and experimentally demonstrate a strategy to overcome this limitation, also for high-loss and long-distance implementations. We exploit the intrinsic wavelength correlations of entangled photons using wavelength multiplexing to generate a quantum secure key from polarization entanglement. The presented approach can be integrated into both fiber- and satellite-based quantum-communication schemes, without any changes to most types of entanglement sources. This technique features a huge scaling potential allowing to increase the secure key rate by several orders of magnitude as compared to non-multiplexed schemes.

Topics & Concepts

Quantum entanglementQuantum key distributionMultiplexingQuantum cryptographyPhoton entanglementComputer scienceQuantum information sciencePhotonKey generationPhysicsQuantum channelQuantum sensorKey (lock)Quantum networkQuantumOpticsCryptographyQuantum informationQuantum mechanicsTelecommunicationsAlgorithmComputer securityQuantum Information and CryptographyQuantum Mechanics and ApplicationsQuantum Computing Algorithms and Architecture
Experimental wavelength-multiplexed entanglement-based quantum cryptography | Litcius