Litcius/Paper detail

Two-photon comb with wavelength conversion and 20-km distribution for quantum communication

Kazuya Niizeki, Daisuke Yoshida, Ko Ito, Ippei Nakamura, Nobuyuki Takei, Kotaro Okamura, Ming-Yang Zheng, Xiu-Ping Xie, Tomoyuki Horikiri

2020Communications Physics21 citationsDOIOpen Access PDF

Abstract

Abstract Quantum computing and quantum communication, have been greatly developed in recent years and expected to contribute to quantum internet technologies, including cloud quantum computing and unconditionally secure communication. However, long-distance quantum communication is challenging mainly because of optical fiber losses; quantum repeaters are indispensable for fiber-based transmission because unknown quantum states cannot be amplified with certainty. In this study, we demonstrate a versatile entanglement source in the telecom band for fiber-based quantum internet, which has a narrow linewidth of sub-MHz range, entanglement fidelity of more than 95%, and Bell-state generation even with frequency multimode. Furthermore, after a total distribution length of 20-km in fiber, two-photon correlation is observed with an easily identifiable normalized correlation coefficient, despite the limited bandwidth of the wavelength converter. The presented implementation promises an efficient method for entanglement distribution that is compatible with quantum memory and frequency-multiplexed long-distance quantum communication applications.

Topics & Concepts

Quantum networkQuantum entanglementQuantum information scienceQuantum key distributionPhysicsQuantum channelQuantum sensorQuantum imagingQuantum technologyQuantum capacityQuantum teleportationQuantumLaser linewidthQuantum mechanicsQuantum correlationQuantum informationAmplitude damping channelTransmission (telecommunications)Quantum error correctionOpen quantum systemQuantum stateQuantum discordQuantum cryptographyQuantum metrologyQuantum computerOptical communicationBandwidth (computing)Computer scienceOpticsWavelengthOptical fiberOptical Network TechnologiesQuantum Information and CryptographyAdvanced Fiber Laser Technologies