A photon-level broadband dual-comb interferometer for turbulent open-air trace gases detection application

TL;DR

This paper introduces a photon-level dual-comb interferometer capable of accurate open-air trace gases detection despite atmospheric turbulence, enabling portable, long-range, and eye-safe environmental sensing.

Contribution

It presents a novel photon-level dual-comb interferometer designed for turbulent open-air environments, overcoming atmospheric path-length variations for enhanced trace gases detection.

Findings

Successfully acquired 20nm broadband absorption spectrum of H13C14N.

Achieved comb-line resolution with quantum-noise-limited SNR.

Demonstrated potential for sensing over hundreds of kilometers.

Abstract

Open-path dual-comb spectroscopy (DCS) significantly enhances our understanding of regional trace gases. However, due to technical challenges, cost considerations, and eye-safety regulations, its sensing range and flexibility remain limited. The photon-counting DCS demonstrated recently heralds potential innovations over open-path DCS. Nevertheless, a major challenge in open-air applications of this approach lies in accurately extracting information from the arrival time of photons that have traversed the turbulent atmosphere. Here, we demonstrate a photon-level dual-comb interferometer for field deployment in open-air environments, uniquely designed to counteract the impact of optical path-length variations caused by atmospheric turbulence and fiber-length wandering. Under variable optical path-length conditions, 20nm broadband absorption spectrum of H13C14N is acquired, with the power per comb line detected as low as 4 attowatt . Furthermore, this photon-level DCS achieves comb-line resolution with a quantum-noise-limited signal-to-noise (SNR). This paves the way for novel open-path DCS applications, including non-cooperative target sensing and sensing over a hundred-kilometers range, all within a portable, fieldable, eye-safety and low power consumption system.