Direct Kerr-frequency-comb atomic spectroscopy
Liron Stern, Jordan R. Stone, Songbai Kang, Daniel C. Cole,, Myoung-Gyun Suh, Connor Fredrick, Zachary Newman, Kerry Vahala, John, Kitching, Scott A Diddams, and Scott B. Papp

TL;DR
This paper demonstrates direct atomic spectroscopy using a microresonator-based frequency comb stabilized to rubidium atoms, achieving high precision and stability for applications in sensing, metrology, and communication.
Contribution
It introduces a method to stabilize microcombs to atomic transitions, enabling precise, integrated optical frequency sources with sub-Doppler resolution.
Findings
Achieved sub-Doppler and hyperfine spectroscopy of rubidium using microcombs.
Stabilized microcomb modes to atomic transition with kilohertz-level fluctuations.
Operates across the 1550 nm band for sensing and communication applications.
Abstract
Microresonator-based soliton frequency combs - microcombs - have recently emerged to offer low-noise, photonic-chip sources for optical measurements. Owing to nonlinear-optical physics, microcombs can be built with various materials and tuned or stabilized with a consistent framework. Some applications require phase stabilization, including optical-frequency synthesis and measurements, optical-frequency division, and optical clocks. Partially stabilized microcombs can also benefit applications, such as oscillators, ranging, dual-comb spectroscopy, wavelength calibration, and optical communications. Broad optical bandwidth, brightness, coherence, and frequency stability have made frequency-comb sources important for studying comb-matter interactions with atoms and molecules. Here, we explore direct microcomb atomic spectroscopy, utilizing a cascaded, two-photon 1529-nm atomic transition…
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Taxonomy
TopicsMass Spectrometry Techniques and Applications · Analytical Chemistry and Sensors · Atomic and Subatomic Physics Research
