Compact laser system with frequency stability dissemination for optical clocks and quantum computing

Abstract: Modern experiments in quantum metrology, sensing, and quantum computing require precise control of the state of atoms and molecules, achieved through the use of highly stable lasers and microwave generators with low phase noise. One of the most effective methods for ensuring high frequency stability is stabilization using a high-finesse Fabry-P\'erot reference cavity. However, implementing separate stabilization systems for each laser increases the complexity and size of the setup, limiting its use to laboratory conditions. An alternative approach is the use of a femtosecond optical frequency comb, which transfers the noise characteristics of a single stabilized frequency reference to other wavelengths in the optical and microwave ranges. In this work, we demonstrate a scheme for transferring frequency stability from an ultrastable laser at 871 nm to a laser at 1550 nm. Measurements using the three-cornered hat method show that the stabilized laser exhibits a fractional frequency instability of less than 4e-15 for averaging times between 0.4 and 2 s, and below 1e-14 for intervals ranging from 0.2 to 500 s. The femtosecond optical frequency comb and the cavity-stabilized laser were designed to meet compactness and portability requirements to enable field and onboard applications.