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Frequency-Domain Quantum Interference with Correlated Photons from an Integrated Microresonator

Chaitali Joshi, Alessandro Farsi, Avik Dutt, Bok Young Kim, Xingchen Ji, Yun Zhao, Andrew M. Bishop, Michal Lipson, Alexander L. Gaeta

2020Physical Review Letters70 citationsDOIOpen Access PDF

Abstract

Frequency encoding of quantum information together with fiber and integrated photonic technologies can significantly reduce the complexity and resource requirements for realizing all-photonic quantum networks. The key challenge for such frequency domain processing of single photons is to realize coherent and selective interactions between quantum optical fields of different frequencies over a range of bandwidths. Here, we report frequency-domain Hong-Ou-Mandel interference with spectrally distinct photons generated from a chip-based microresonator. We use four-wave mixing to implement an active "frequency beam splitter" and achieve interference visibilities of 0.95±0.02. Our work establishes four-wave mixing as a tool for selective high-fidelity two-photon operations in the frequency domain which, combined with integrated single-photon sources, provides a building block for frequency-multiplexed photonic quantum networks.

Topics & Concepts

PhotonPhotonicsPhysicsBeam splitterInterference (communication)Frequency domainQuantum sensorQuantum opticsQuantum information scienceQuantum networkQuantumQuantum technologyQuantum informationOptoelectronicsOpticsQuantum entanglementComputer scienceTelecommunicationsQuantum mechanicsOpen quantum systemLaserComputer visionChannel (broadcasting)Photonic and Optical DevicesQuantum Information and CryptographyQuantum optics and atomic interactions
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