Precise synchronization between distant clocks plays an essential role in almost all types of precision measurements. Compared with the traditional methods based on satellites, fiber optics is an advantageous channel for precise time and frequency transfer.
Further cooperating with quantum technology, the fiber-optic quantum clock synchronization has shown great potential in enhancing the precision and providing better guarantee of security.
To further prove its advantages in practical applications, a research team from National Time Service Center of the Chinese Academy of Sciences implemented two tests of synchronization performance between clocks apart on two types of optical fiber distances (7-km intracity fiber link and 50-km laboratory fiber link).
The results were published in Optics Express and Journal of Lightwave Technology, respectively.
For the field test of two-way quantum synchronization between a H-maser located at the campus of NTSC and a Rb clock at LiShan Observatory (LSO) linked by a 7-km-long deployed fiber, results showed that the short-term synchronization stability reached the intrinsic frequency stability of the Rb clock to the H-maser, which was measured as 32 ps at 30 s. The long-term synchronization stability achieved 19.3 ps at 7680 s.
"This experiment proves the high potential of the two-way quantum clock synchronization in field applications to promote the synchronization performance," said Prof. DONG Ruifang from NTSC.
Meanwhile, the research team demonstrated a fiber-optic two-way quantum clock synchronization experiment on a laboratory fiber with the distance reaching 50 km. With the common reference clock, a synchronization stability of 54.6 fs at 57300 s and an accuracy of 1.3 ps±36.6 ps were achieved.
"The achieved results in the experiment have promised a bright future of the two-way quantum clock synchronization for realizing femtosecond-scale-precision synchronization on metropolitan fiber links," said Prof. DONG.
These implementations show the potential of the two-way quantum clock synchronization in enhancing the synchronization precision of field applications based on metropolitan optical fiber links.
