Dual-comb correlation spectroscopy reveals laser dynamics

TL;DR

Dual-comb correlation spectroscopy (DCCS) is introduced as a high-resolution, rapid method for analyzing complex laser dynamics, surpassing traditional spectroscopic techniques in resolving fast, broadband, and intricate behaviors.

Contribution

The paper presents DCCS as a novel spectroscopic technique capable of capturing fast, broadband laser dynamics with high resolution, addressing limitations of existing methods like TS-DFT.

Findings

Revealed mode-hopping and mode-competition in continuous-wave lasers

Demonstrated buildup process of a mode-locked laser

Achieved rapid spectral retrieval over broad bandwidths

Abstract

Laser dynamics underpin a broad range of modern photonic technologies and continue to reveal rich nonlinear behaviors. However, existing spectroscopic tools, most notably time-stretched dispersive Fourier transform spectroscopy (TS-DFT), remain limited in spectral resolution, accuracy, and their ability to capture continuous waveforms and complex field dynamics. Here, we introduce dual-comb correlation spectroscopy (DCCS) as a powerful approach for resolving fast and intricate laser behaviors that are inaccessible to TS-DFT and conventional spectrometers. By correlating two sequences of heterodyne spectra produced by mixing a test laser with a pair of optical combs, DCCS enables rapid (e.g., 1 us) and high-resolution (0.08 pm) spectral retrieval over broad optical bandwidths. Leveraging these capabilities, we reveal mode-hopping and mode-competition dynamics in continuous-wave lasers, as well as the buildup process of a mode-locked laser. These results establish DCCS as a versatile and complementary tool to TS-DFT for exploring transient, broadband, and previously unresolvable behaviors in lasers and other time-evolving optical systems.