Related papers: Quantum key distribution over 658 km fiber with distributed vibration sensing

Quantum key distribution over 658 km fiber with distributed vibration sensing

URL: http://arxiv.org/abs/2110.11671v1
Date: Fri, 22 Oct 2021 09:12:41 GMT
Title: Quantum key distribution over 658 km fiber with distributed vibration sensing
Authors: Jiu-Peng Chen, Chi Zhang, Yang Liu, Cong Jiang, Dong-Feng Zhao, Wei-Jun Zhang, Fa-Xi Chen, Hao Li, Li-Xing You, Zhen Wang, Yang Chen, Xiang-Bin Wang, Qiang Zhang and Jian-Wei Pan
Abstract summary: Twin-field quantum key distribution (TF-QKD) promises ultra-long secure key distribution which surpasses the rate distance limit and can reduce the number of trusted nodes in long-haul quantum network. Here, we demonstrate the sending-or-not-sending TF-QKD experimentally, achieving a secure key distribution with finite size analysis over 658 km ultra-low-loss optical fiber. Our results not only set a new distance record of QKD, but also demonstrate that the redundant information of TF-QKD can be used for remote sensing of the channel vibration.
Score: 20.764613385086037
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Twin-field quantum key distribution (TF-QKD) promises ultra-long secure key distribution which surpasses the rate distance limit and can reduce the number of the trusted nodes in long-haul quantum network. Tremendous efforts have been made towards implementation of TF-QKD, among which, the secure key with finite size analysis can distribute more than 500 km in the lab and in the field. Here, we demonstrate the sending-or-not-sending TF-QKD experimentally, achieving a secure key distribution with finite size analysis over 658 km ultra-low-loss optical fiber, improve the secure distance record by around 100 km. Meanwhile, in a TF-QKD system, any phase fluctuation due to temperature variation and ambient variation during the channel must be recorded and compensated, and all these phase information can then be utilized to sense the channel vibration perturbations. With our QKD system, we recovered the external vibrational perturbations on the fiber generated by an artificial vibroseis and successfully located the perturbation position with a resolution better than 1 km. Our results not only set a new distance record of QKD, but also demonstrate that the redundant information of TF-QKD can be used for remote sensing of the channel vibration, which can find applications in earthquake detection and landslide monitoring besides secure communication.

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