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Designing noise-robust quantum networks coexisting in the classical fiber infrastructure

Jordan M. Thomas, Gregory S. Kanter, Prem Kumar

2023Optics Express37 citationsDOIOpen Access PDF

Abstract

The scalability of quantum networking will benefit from quantum and classical communications coexisting in shared fibers, the main challenge being spontaneous Raman scattering noise. We investigate the coexistence of multi-channel O-band quantum and C-band classical communications. We characterize multiple narrowband entangled photon pair channels across 1282 nm-1318 nm co-propagating over 48 km of installed standard fiber with record C-band power (>18 dBm) and demonstrate that some quantum-classical wavelength combinations significantly outperform others. We analyze the Raman noise spectrum, optimal wavelength engineering, multi-photon pair emission in entangled photon-classical coexistence, and evaluate the implications for future quantum applications.

Topics & Concepts

Quantum networkQuantumQuantum channelRaman scatteringPhotonNarrowbandPhysicsQuantum information scienceNoise (video)Quantum opticsOpticsTelecommunicationsQuantum informationRaman spectroscopyQuantum mechanicsQuantum entanglementComputer scienceImage (mathematics)Artificial intelligenceQuantum Information and CryptographyQuantum Mechanics and ApplicationsQuantum optics and atomic interactions
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