A frequency shift compensation method for light shift and vapor-cell temperature shift in atomic clocks
Abstract
Light shift and vapor-cell temperature shift are the two most significant factors dominating the long-term instability of compact atomic clocks. Due to the different physical mechanisms, there is not yet a solution that can effectively suppress the frequency shifts induced by these two effects. Here, we propose a 'resonance-offset' locking approach that compensates for the two physical frequency shifts. In this approach, the additional offset locking shift can effectively counteract the atomic resonance shifts arising from changes in vapor-cell temperature and light power, reducing the net impact on the clock's frequency to nearly zero. We have demonstrated this strategy on the 778 nm Rubidium two-photon optical frequency standard, successfully compensating for light shift and cell-temperature shift, respectively. This general method is particularly appealing for compact vapor-cell microwave and optical atomic clocks designed for the excellent stability rather than accuracy.
Keywords
Cite
@article{arxiv.2405.14281,
title = {A frequency shift compensation method for light shift and vapor-cell temperature shift in atomic clocks},
author = {Dou Li and Kangqi Liu and Linzhen Zhao and Songbai Kang},
journal= {arXiv preprint arXiv:2405.14281},
year = {2024}
}
Comments
12 pages, 8 figures