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Fiber-Optic quantum two-way time transfer with frequency entangled pulses

Quantum Physics 2019-09-04 v2

Abstract

High-precision time transfer is of fundamental interest in physics and metrology. Quantum time transfer technologies that use frequency-entangled pulses and their coincidence detection have been proposed, offering potential enhancements in precision and better guarantees of security. In this paper, we describe a fiber-optic two-way quantum time transfer experiment. Using quantum nonlocal dispersion cancellation, time transfer over a 20-km fiber link achieves a time deviation of 922 fs over 5 s and 45 fs over 40960 s. The time transfer accuracy as a function of fiber lengths from 15 m to 20 km is also investigated, and an uncertainty of 2.46 ps in standard deviation is observed. In comparison with its classical counterparts, the fiber-optic two-way quantum time transfer setup shows appreciable improvement, and further enhancements could be obtained by using new event timers with sub-picosecond precision and single-photon detectors with lower timing jitter for optimized coincidence detection. Combined with its security advantages, the femtosecond-scale two-way quantum time transfer is expected to have numerous applications in high-precision middle-haul synchronization systems.

Keywords

Cite

@article{arxiv.1812.10077,
  title  = {Fiber-Optic quantum two-way time transfer with frequency entangled pulses},
  author = {Feiyan Hou and Runai Quan and Ruifang Dong and Xiao Xiang and Baihong Li and Tao Liu and Xiaoyan Yang and Hao Li and Lixing You and Zhen Wang and Shougang Zhang},
  journal= {arXiv preprint arXiv:1812.10077},
  year   = {2019}
}

Comments

10 pages, 7 figures

R2 v1 2026-06-23T06:55:43.810Z