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Continuous entanglement distribution from an AlGaAs-on-insulator microcomb for quantum communications

Trevor J. Steiner, Maximilian Shen, Joshua E. Castro, John E. Bowers, Galan Moody

2023Optica Quantum19 citationsDOIOpen Access PDF

Abstract

Using an aluminum gallium arsenide microring resonator, we demonstrate a bright quantum optical microcomb with >300 nm (>40 THz) bandwidth and more than 20 sets of time–energy entangled modes, enabling spectral demultiplexing with simple, off-the-shelf commercial telecom components. We report high-rate continuous entanglement distribution for two sets of entangled-photon pair frequency modes exhibiting up to 20 GHz/mW 2 pair generation rate. As an illustrative example of entanglement distribution, we perform a continuous-wave time-bin quantum key distribution protocol with 8 kbps sifted key rates while maintaining less than 10% error rate and sufficient two-photon visibility to ensure security of the channel. When the >20 frequency modes are multiplexed, we estimate >100 kbps entanglement-based key rates or the creation of a multi-user quantum communications network. The entire system requires less than 110 µW of on-chip optical power, demonstrating an efficient source of entangled frequency modes for quantum communications. As a proof of principle, a quantum key is distributed across 12 km of deployed fiber on the University of California Santa Barbara (UCSB) campus and used to encrypt a 21 kB image with <9% error.

Topics & Concepts

Quantum key distributionQuantum entanglementPhysicsQuantum networkPhoton entanglementQuantum channelComputer scienceMultiplexingQuantum teleportationQuantum information sciencePhotonOptoelectronicsOpticsTelecommunicationsQuantumQuantum mechanicsQuantum Information and CryptographyAdvanced Fiber Laser TechnologiesMechanical and Optical Resonators
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