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High-dimensional time-frequency entanglement in a singly-filtered biphoton frequency comb

Xiang Cheng, Kai-Chi Chang, Murat Can Sarihan, Andrew Mueller, M. Spiropulu, Matthew D. Shaw, Boris Korzh, Andrei Faraon, Franco N. C. Wong, Jeffrey H. Shapiro, Chee Wei Wong

2023Communications Physics21 citationsDOIOpen Access PDF

Abstract

Abstract High-dimensional quantum entanglement is a cornerstone for advanced technology enabling large-scale noise-tolerant quantum systems, fault-tolerant quantum computing, and distributed quantum networks. The recently developed biphoton frequency comb (BFC) provides a powerful platform for high-dimensional quantum information processing in its spectral and temporal quantum modes. Here we propose and generate a singly-filtered high-dimensional BFC via spontaneous parametric down-conversion by spectrally shaping only the signal photons with a Fabry-Pérot cavity. High-dimensional energy-time entanglement is verified through Franson-interference recurrences and temporal correlation with low-jitter detectors. Frequency- and temporal- entanglement of our singly-filtered BFC is then quantified by Schmidt mode decomposition. Subsequently, we distribute the high-dimensional singly-filtered BFC state over a 10 km fiber link with a post-distribution time-bin dimension lower bounded to be at least 168. Our demonstrations of high-dimensional entanglement and entanglement distribution show the singly-filtered quantum frequency comb’s capability for high-efficiency quantum information processing and high-capacity quantum networks.

Topics & Concepts

Quantum entanglementPhysicsQuantum sensorQuantum networkPhotonQuantumQuantum information scienceQuantum metrologyQuantum mechanicsQuantum Information and CryptographyAdvanced Fiber Laser TechnologiesMechanical and Optical Resonators