Coherent injection locking of quantum cascade laser frequency combs

TL;DR

This paper demonstrates that coherent injection locking can stabilize quantum cascade laser frequency combs, enabling on-chip dual-comb spectroscopy and overcoming previous feedback-related limitations.

Contribution

It introduces the first demonstration of phase-locked injection locking of QCL frequency combs, enhancing stability and integration potential.

Findings

Injection locking stabilizes QCL frequency combs.

The spectrum can be phase-locked to a RF oscillator.

A prototype dual-comb setup shows potential for on-chip spectroscopy.

Abstract

Quantum cascade laser (QCL) frequency combs are a promising candidate for chemical sensing and biomedical diagnostics, requiring only milliseconds of acquisition time to record absorption spectra without any moving parts. They are electrically pumped and have a small footprint, making them an ideal platform for on-chip integration. Until now, optical feedback is fatal for frequency comb generation in QCLs and destroys intermodal coherence. This property imposes strict limits on the possible degree of integration. Here, we demonstrate coherent injection locking of the repetition frequency to a stabilized RF oscillator. For the first time, we prove that the spectrum of the injection locked QCL can be phase-locked, resulting in the generation of a frequency comb. We show that injection locking is not only a versatile tool for all-electrical frequency stabilization, but also mitigates the fatal effect of optical feedback on the frequency comb. A prototype self-detected dual-comb setup consisting only of an injection locked dual-comb chip, a lens and a mirror demonstrates the enormous potential for on-chip dual-comb spectroscopy. These results pave the way to miniaturized and all-solid-state mid-infrared spectrometers.