English

Faraday laser pumped cesium beam clock

Atomic Physics 2024-07-12 v2

Abstract

We realize a high-performance compact optically pumped cesium beam clock using Faraday laser simultaneously as pumping and detection lasers. The Faraday laser, which is frequency stabilized by modulation transfer spectroscopy (MTS) technique, has narrow linewidth and superior frequency stability. Measured by optical heterodyne method between two identical systems, the linewidth of the Faraday laser is 2.5 kHz after MTS locking, and the fractional frequency stability of the Faraday laser is optimized to 1.8×1012/τ1.8\times{10}^{-12}/\sqrt{\tau}. Based on this high-performance Faraday laser, the cesium beam clock realizes a signal-to-noise ratio (SNR) in 1 Hz bandwidth of 3960039600 when the cesium oven temperature is 130{\deg}C. Frequency-compared with Hydrogen maser, the fractional frequency stability of the Faraday laser pumped cesium beam clock can reach 1.3×1012/τ1.3\times{10}^{-12}/\sqrt{\tau} and drops to 1.4×10141.4\times{10}^{-14} at 10000 s when the cesium oven temperature is 110{\deg}C. %, which is the best reported result compared with other cesium beam clocks. This Faraday laser pumped cesium beam clock demonstrates its excellent performance, and its great potential in the fields of timekeeping, navigation, and communication. Meanwhile, the Faraday laser, as a high-performance optical frequency standard, can also contribute to the development of other applications in quantum metrology, precision measurement and atomic physics.

Keywords

Cite

@article{arxiv.2407.06067,
  title  = {Faraday laser pumped cesium beam clock},
  author = {Hangbo Shi and Xiaomin Qin and Haijun Chen and Yufei Yan and Ziqi Lu and Zhiyang Wang and Zijie Liu and Xiaolei Guan and Qiang Wei and Tiantian Shi and Jingbiao Chen},
  journal= {arXiv preprint arXiv:2407.06067},
  year   = {2024}
}
R2 v1 2026-06-28T17:33:05.361Z