Cavity-enhanced dual-comb spectroscopy
Abstract
The sensitivity of molecular fingerprinting is dramatically improved when placing the absorbing sample in a high-finesse optical cavity, thanks to the large increase of the effective path-length. As demonstrated recently, when the equidistant lines from a laser frequency comb are simultaneously injected into the cavity over a large spectral range, multiple trace-gases may be identified within a few milliseconds. Analyzing efficiently the light transmitted through the cavity however still remains challenging. Here, a novel approach, cavity-enhanced frequency comb Fourier transform spectroscopy, fully overcomes this difficulty and measures ultrasensitive, broad-bandwidth, high-resolution spectra within a few tens of s. It could be implemented from the Terahertz to the ultraviolet regions without any need for detector arrays. We recorded, within 18 s, spectra of the 1.0 m overtone bands of ammonia spanning 20 nm with 4.5 GHz resolution and a noise-equivalent-absorption at one-second-averaging per spectral element of 3 10^-12 cm^-1Hz^-1/2, thus opening a route to time-resolved spectroscopy of rapidly-evolving single-events.
Cite
@article{arxiv.0908.1928,
title = {Cavity-enhanced dual-comb spectroscopy},
author = {Birgitta Bernhardt and Akira Ozawa and Patrick Jacquet and Marion Jacquey and Yohei Kobayashi and Thomas Udem and Ronald Holzwarth and Guy Guelachvili and Theodor W. Hänsch and Nathalie Picqué},
journal= {arXiv preprint arXiv:0908.1928},
year = {2015}
}