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Autores principales: Yuan, Yi, Cao, Jian, Yuan, Jinbo, Wang, Dehao, Fang, Pengcheng, Chen, Qunfeng, Cao, Shiying, Wang, Xuanjian, Chao, Sijia, Shu, Hualin, Li, Guojun, Xu, Jinfeng, Fu, Guitao, Yang, Yuting, Zhao, Run, Shi, Fengfeng, Huang, Xueren
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2510.12454
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author Yuan, Yi
Cao, Jian
Yuan, Jinbo
Wang, Dehao
Fang, Pengcheng
Chen, Qunfeng
Cao, Shiying
Wang, Xuanjian
Chao, Sijia
Shu, Hualin
Li, Guojun
Xu, Jinfeng
Fu, Guitao
Yang, Yuting
Zhao, Run
Shi, Fengfeng
Huang, Xueren
author_facet Yuan, Yi
Cao, Jian
Yuan, Jinbo
Wang, Dehao
Fang, Pengcheng
Chen, Qunfeng
Cao, Shiying
Wang, Xuanjian
Chao, Sijia
Shu, Hualin
Li, Guojun
Xu, Jinfeng
Fu, Guitao
Yang, Yuting
Zhao, Run
Shi, Fengfeng
Huang, Xueren
contents Precise time scale is the universal base for all measurements. Here we report the deployment of a compact and transportable optical clock to a timekeeping institution and steering an active hydrogen maser to generate an optical time scale, realizing the upgrade of the local time scale in the Global Navigation Satellite System. The optical clock was transported over 1200 km by express delivery and resume work as normal promptly, and its extremely high uptime of 93.6% in the half-year enabled us to precisely correct the frequency drift of hydrogen maser, ultimately achieving an unprecedented monthly instability of 4E-17. This steering experiment with a deployable optical clock marks a significant advancement, demonstrating that a timing accuracy below 100 ps per month can be achieved feasibly in various timekeeping institutions where hydrogen masers are typically employed as the primary contributor to timekeeping. In the future, mobile optical time scale based on such transportable optical clock can be deployed flexibly and rapidly, which is particularly important in scenarios lacking International Atomic Time reference.
format Preprint
id arxiv_https___arxiv_org_abs_2510_12454
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle First GNSS-deployed optical clock for local time scale upgrade
Yuan, Yi
Cao, Jian
Yuan, Jinbo
Wang, Dehao
Fang, Pengcheng
Chen, Qunfeng
Cao, Shiying
Wang, Xuanjian
Chao, Sijia
Shu, Hualin
Li, Guojun
Xu, Jinfeng
Fu, Guitao
Yang, Yuting
Zhao, Run
Shi, Fengfeng
Huang, Xueren
Atomic Physics
Optics
Precise time scale is the universal base for all measurements. Here we report the deployment of a compact and transportable optical clock to a timekeeping institution and steering an active hydrogen maser to generate an optical time scale, realizing the upgrade of the local time scale in the Global Navigation Satellite System. The optical clock was transported over 1200 km by express delivery and resume work as normal promptly, and its extremely high uptime of 93.6% in the half-year enabled us to precisely correct the frequency drift of hydrogen maser, ultimately achieving an unprecedented monthly instability of 4E-17. This steering experiment with a deployable optical clock marks a significant advancement, demonstrating that a timing accuracy below 100 ps per month can be achieved feasibly in various timekeeping institutions where hydrogen masers are typically employed as the primary contributor to timekeeping. In the future, mobile optical time scale based on such transportable optical clock can be deployed flexibly and rapidly, which is particularly important in scenarios lacking International Atomic Time reference.
title First GNSS-deployed optical clock for local time scale upgrade
topic Atomic Physics
Optics
url https://arxiv.org/abs/2510.12454