Laser self-injection locking to fiber Fabry-Perot resonator for frequency comb generation

TL;DR

This paper demonstrates that self-injection locking of a DFB laser to a fiber Fabry-Perot resonator enables low-power optical frequency comb generation, including cavity solitons, with detailed modeling and analysis of the dynamics involved.

Contribution

It introduces a novel approach of using SIL with a fiber FFP resonator for stable, low-power OFC generation and provides a comprehensive analysis of the system's dynamics and stability.

Findings

SIL enables OFC generation at as low as 100 mW power.

Cavity solitons are observed in the system.

The initial phase of the fiber link critically affects locking stability.

Abstract

This study demonstrates that self-injection locking (SIL) of a distributed feedback (DFB) laser to a high-Q fiber Fabry Perot (FFP) resonator, fabricated with highly nonlinear fiber, allows optical frequency combs (OFC) generation with a laser power as low as 100 mW. More precisely, cavity soliton (CS) regime has been observed in this configuration, along with other types of combs. The laser stabilization using SIL is described. Then the system's behavior is analyzed through modeling the laser's dynamics and comparing the model results to experimental tuning curve measurements. Our findings highlight the critical role of the initial phase of the fiber link between laser and FFP in determining the stability and effectiveness of the locking process. We explore the dynamics of the nonlinear SIL process while varying the laser current, revealing the transition from modulation instability to chaotic comb states, and eventually to soliton formation as the system moves from an effective blue-detuned to an effective red-detuned regime. Notably, the inclusion of self-phase modulation (SPM) in the SIL model predicts accessibility of the narrow soliton existence range. These results highlight the potential of SIL in FFP resonators for low-power, stable OFC generation, offering a promising path forward for practical applications.