Litcius/Paper detail

Sideband injection locking in microresonator frequency combs

Thibault Wildi, Alexander E. Ulanov, Nicolas Englebert, Thibault Voumard, Tobias Herr

2023APL Photonics36 citationsDOIOpen Access PDF

Abstract

Frequency combs from continuous-wave-driven Kerr-nonlinear microresonators have evolved into a key photonic technology with applications from optical communication to precision spectroscopy. Essential to many of these applications is the control of the comb’s defining parameters, i.e., carrier-envelope offset frequency and repetition rate. An elegant and all-optical approach to controlling both degrees of freedom is the suitable injection of a secondary continuous-wave laser into the resonator onto which one of the comb lines locks. Here, we experimentally study such sideband injection locking in microresonator soliton combs across a wide optical bandwidth and derive analytic scaling laws for the locking range and repetition rate control. As an application example, we demonstrate optical frequency division and repetition rate phase-noise reduction to three orders of magnitude below the noise of a free-running system. The presented results can guide the design of sideband injection-locked, parametrically generated frequency combs with opportunities for low-noise microwave generation, compact optical clocks with simplified locking schemes, and, more generally, all-optically stabilized frequency combs from Kerr-nonlinear resonators.

Topics & Concepts

Frequency combPhysicsOpticsInjection lockingPhase noiseFree spectral rangeResonatorComb generatorSidebandMode-lockingBandwidth (computing)Optical Carrier transmission ratesPhotonicsLaserMicrowaveOptical fiberTelecommunicationsComputer scienceRadio over fiberQuantum mechanicsAdvanced Fiber Laser TechnologiesPhotonic and Optical DevicesLaser-Matter Interactions and Applications