Picosecond Synchronization System for Quantum Networks

Raju Valivarthi; Lautaro Narváez; Samantha I. Davis; Nikolai Lauk; Cristián Peña; Si Xie; Jason P. Allmaras; Andrew D. Beyer; Boris Korzh; Andrew Mueller; Mandy Kiburg; Matthew D. Shaw; Emma E. Wollman; Panagiotis Spentzouris; Daniel Oblak; Neil Sinclair; Maria Spiropulu

Journal of Lightwave Technology
Vol. 40,
Issue 23,
pp. 7668-7675
(2022)

Picosecond Synchronization System for Quantum Networks

Raju Valivarthi, Lautaro Narváez, Samantha I. Davis, Nikolai Lauk, Cristián Peña, Si Xie, Jason P. Allmaras, Andrew D. Beyer, Boris Korzh, Andrew Mueller, Mandy Kiburg, Matthew D. Shaw, Emma E. Wollman, Panagiotis Spentzouris, Daniel Oblak, Neil Sinclair, and Maria Spiropulu

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Raju Valivarthi, Lautaro Narváez, Samantha I. Davis, Nikolai Lauk, Cristián Peña, Si Xie, Jason P. Allmaras, Andrew D. Beyer, Boris Korzh, Andrew Mueller, Mandy Kiburg, Matthew D. Shaw, Emma E. Wollman, Panagiotis Spentzouris, Daniel Oblak, Neil Sinclair, and Maria Spiropulu, "Picosecond Synchronization System for Quantum Networks," J. Lightwave Technol. 40, 7668-7675 (2022)

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Abstract

The operation of long-distance quantum networks requires photons to be synchronized and must account for length variations of quantum channels. We demonstrate a 200 MHz clock-rate fiber optic-based telecommunication C-band quantum network using off-the-shelf components combined with custom-made electronics. The network is backed by a scalable and fully automated synchronization system with ps-scale timing resolution. Synchronization of the photons is achieved by distributing O-band-wavelength laser pulses between network nodes. Specifically, we distribute photon pairs between three nodes, and measure a reduction of coincidence-to-accidental ratio from 77 to only 42 when the synchronization system is enabled, which permits high-fidelity qubit transmission. Our demonstration sheds light on the role of noise in quantum communication and represents a key step in realizing deployed co-existing classical-quantum networks.

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Journal of Lightwave Technology