Wavelength multicasting quantum clock synchronization network

AAPPS Bulletin Pub Date : 2024-11-18 DOI:10.1007/s43673-024-00136-4

Jiaao Li, Hui Han, Xiaopeng Huang, Bangying Tang, Kai Guo, Jinquan Huang, Siyu Xiong, Wanrong Yu, Zhaojian Zhang, Junbo Yang, Bo Liu, Huan Chen, Zhenkun Lu

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Abstract

Quantum clock synchronization (QCS) can measure out the high-precision clock difference among distant users, which breaks through the standard quantum limit by employing the properties of quantum entanglement. Currently, the wavelength division multiplexed QCS network has been demonstrated with a spontaneous parametric down-conversion entangled photon source. In this paper, we propose a more efficient QCS network scheme with the wavelength multicasting entangled photon source, which can decrease at least 25% of wavelength channel consumption under the identical network scale. Afterwards, a four node QCS network is demonstrated, where the wavelength multicasting entangled photon source is utilized with dual-pumped four-wave mixing silicon chip. The experimental results show that the measured time deviation is 3.4 ps with an average time of 640 s via the multiple fiber links of more than 10 km.

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波长多播量子时钟同步网络

量子时钟同步（QCS）可以测量出远距离用户之间的高精度时钟差，它利用量子纠缠的特性突破了标准量子极限。目前，利用自发参量下变频纠缠光子源的波分复用 QCS 网络已经得到验证。本文提出了一种采用波长多播纠缠光子源的更高效 QCS 网络方案，在网络规模相同的情况下，可减少至少 25% 的波长信道消耗。随后，演示了一个四节点 QCS 网络，其中波长多播纠缠光子源与双泵浦四波混合硅芯片配合使用。实验结果表明，通过超过 10 千米的多条光纤链路，测得的时间偏差为 3.4 ps，平均时间为 640 s。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

AAPPS Bulletin

CiteScore

8.20

自引率

0.00%

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