# Fully phase-stabilized quantum cascade laser frequency comb

**Authors:** Luigi Consolino, Malik Nafa, Francesco Cappelli, Katia Garrasi,, Francesco P. Mezzapesa, Lianhe Li, A. Giles Davies, Edmund H. Linfield,, Miriam S. Vitiello, Paolo De Natale, Saverio Bartalini

arXiv: 1902.01604 · 2019-09-11

## TL;DR

This paper reports the development of a fully stabilized quantum cascade laser frequency comb that achieves precise control and measurement of its modes, enabling advanced applications in mid- and far-infrared quantum technologies.

## Contribution

It introduces a novel technique for full stabilization and control of QCL-comb parameters against primary standards, achieving Hz-level mode narrowing and high-accuracy frequency measurement.

## Key findings

- Hz-level narrowing of comb modes
- Metrological-grade tuning of individual frequencies
- Achieved frequency measurement accuracy of 2x10^-12

## Abstract

Optical frequency comb synthesizers (FCs) [1] are laser sources covering a broad spectral range with a number of discrete, equally spaced and highly coherent frequency components, fully controlled through only two parameters: the frequency separation between adjacent modes and the carrier offset frequency. Providing a phase-coherent link between the optical and the microwave/radio-frequency regions [2], FCs have become groundbreaking tools for precision measurements[3,4].   Despite these inherent advantages, developing miniaturized comb sources across the whole infrared (IR), with an independent and simultaneous control of the two comb degrees of freedom at a metrological level, has not been possible, so far. Recently, promising results have been obtained with compact sources, namely diode-laser-pumped microresonators [5,6] and quantum cascade lasers (QCL-combs) [7,8]. While both these sources rely on four-wave mixing (FWM) to generate comb frequency patterns, QCL-combs benefit from a mm-scale miniaturized footprint, combined with an ad-hoc tailoring of the spectral emission in the 3-250 {\mu}m range, by quantum engineering [9].   Here, we demonstrate full stabilization and control of the two key parameters of a QCL-comb against the primary frequency standard. Our technique, here applied to a far-IR emitter and open ended to other spectral windows, enables Hz-level narrowing of the individual comb modes, and metrological-grade tuning of their individual frequencies, which are simultaneously measured with an accuracy of 2x10^-12, limited by the frequency reference used. These fully-controlled, frequency-scalable, ultra-compact comb emitters promise to pervade an increasing number of mid- and far-IR applications, including quantum technologies, due to the quantum nature of the gain media [10].

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Source: https://tomesphere.com/paper/1902.01604