单根光纤中并存量子和经典信号的 100 公里纠缠分布

IF 4 2区 计算机科学 Q1 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
A. Rahmouni;P. S. Kuo;Y. S. Li-Baboud;I. A. Burenkov;Y. Shi;M. V. Jabir;N. Lal;D. Reddy;M. Merzouki;L. Ma;A. Battou;S. V. Polyakov;O. Slattery;T. Gerrits
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引用次数: 0

摘要

城域量子网络原型的开发工作正在进行中,需要通过部署在几十公里长的光纤中的单光子传输量子信息。建立城域量子网络的主要挑战是偏振波动补偿、高精度时钟同步和累积传输时间波动补偿。应对这些挑战的一种方法是在与量子信号相同的光纤中共同传播经典探测信号。这样,两个信号就会经历相同的条件,从而可以监测和补偿光纤的变化。在这里,我们展示了偏振纠缠量子信号与白兔精密时间协议经典信号在同一根单芯光纤中以大都市尺度的距离共传播的分布情况。我们的研究结果证明了这种量子-经典共存的可行性,在相隔 100 千米光纤的节点之间实现了高保真纠缠分发。这一进展是朝着实际实现稳健高效的城域量子网络迈出的重要一步。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
100-km entanglement distribution with coexisting quantum and classical signals in a single fiber
The development of prototype metropolitan-scale quantum networks is underway and entails transmitting quantum information via single photons through deployed optical fibers spanning several tens of kilometers. The major challenges in building metropolitan-scale quantum networks are compensation for polarization fluctuation, high-precision clock synchronization, and compensation for cumulative transmission time fluctuations. One approach addressing these challenges is to copropagate classical probe signals in the same fiber as the quantum signal. Thus, both signals experience the same conditions, and the changes of the fiber can therefore be monitored and compensated. Here, we demonstrate the distribution of polarization-entangled quantum signals copropagating with the White Rabbit precision time protocol classical signals in the same single-core fiber strand at metropolitan-scale distances. Our results demonstrate the feasibility of this quantum-classical coexistence by achieving high-fidelity entanglement distribution between nodes separated by 100 km of optical fiber. This advancement is a significant step towards the practical implementation of robust and efficient metropolitan-scale quantum networks.
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来源期刊
CiteScore
9.40
自引率
16.00%
发文量
104
审稿时长
4 months
期刊介绍: The scope of the Journal includes advances in the state-of-the-art of optical networking science, technology, and engineering. Both theoretical contributions (including new techniques, concepts, analyses, and economic studies) and practical contributions (including optical networking experiments, prototypes, and new applications) are encouraged. Subareas of interest include the architecture and design of optical networks, optical network survivability and security, software-defined optical networking, elastic optical networks, data and control plane advances, network management related innovation, and optical access networks. Enabling technologies and their applications are suitable topics only if the results are shown to directly impact optical networking beyond simple point-to-point networks.
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