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Bibliographic Details
Main Authors: Millet, Loïc, Korzh, Boris, Thew, Rob, Boso, Gianluca
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.26705
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author Millet, Loïc
Korzh, Boris
Thew, Rob
Boso, Gianluca
author_facet Millet, Loïc
Korzh, Boris
Thew, Rob
Boso, Gianluca
contents Clock synchronization is critical for maintaining low error rates in quantum key distribution. Here, we describe how a frequency mismatch between the transmitter and receiver clocks affects the quantum bit error rate in quantum key distribution, and derive from this model a simple synchronization algorithm together with clock stability requirements for practical operation. Our algorithm continuously compensates for both frequency mismatch and time-offset fluctuations directly from detection timestamps. It does not require a dedicated synchronization channel or auxiliary qubit sequence, converges from a large frequency mismatch within approximately one second of photon acquisition, and remains effective in low-photon-count regimes (more than 30 dB of channel loss) using standard hardware. We validate our approach by demonstrating successful key exchange over 100 km of fiber and continuous operation over 24 hours in a 16 km metropolitan network using commercial systems, with performance equivalent to using a service channel for clock synchronization.
format Preprint
id arxiv_https___arxiv_org_abs_2605_26705
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Analytical Model of Clock Drift in Quantum Key Distribution and a Simple Synchronization Algorithm
Millet, Loïc
Korzh, Boris
Thew, Rob
Boso, Gianluca
Quantum Physics
Clock synchronization is critical for maintaining low error rates in quantum key distribution. Here, we describe how a frequency mismatch between the transmitter and receiver clocks affects the quantum bit error rate in quantum key distribution, and derive from this model a simple synchronization algorithm together with clock stability requirements for practical operation. Our algorithm continuously compensates for both frequency mismatch and time-offset fluctuations directly from detection timestamps. It does not require a dedicated synchronization channel or auxiliary qubit sequence, converges from a large frequency mismatch within approximately one second of photon acquisition, and remains effective in low-photon-count regimes (more than 30 dB of channel loss) using standard hardware. We validate our approach by demonstrating successful key exchange over 100 km of fiber and continuous operation over 24 hours in a 16 km metropolitan network using commercial systems, with performance equivalent to using a service channel for clock synchronization.
title Analytical Model of Clock Drift in Quantum Key Distribution and a Simple Synchronization Algorithm
topic Quantum Physics
url https://arxiv.org/abs/2605.26705