Universal Kerr-thermal dynamics of self-injection-locked microresonator dark pulses

TL;DR

This paper explores the universal Kerr-thermal dynamics behind dark-pulse formation in self-injection-locked microresonator systems, combining theory, simulation, and experiments to reveal new behaviors and applications in low-noise microwave generation.

Contribution

It introduces a comprehensive theoretical model for Kerr-thermal effects in self-injection-locked microresonators, advancing understanding of dark-pulse microcomb formation and switching.

Findings

Unveiled universal dark-pulse formation and switching behavior.

Validated the theoretical model with numerical simulations and experiments.

Demonstrated low-noise microwave generation with 23.5 dB phase noise improvement.

Abstract

Microcombs, formed in optical microresonators driven by continuous-wave lasers, are miniaturized optical frequency combs. Leveraging integrated photonics and laser self-injection locking (SIL), compact microcombs can be constructed via hybrid integration of a semiconductor laser with a chip-based microresonator. While the current linear SIL theory has successfully addressed the linear coupling between the laser cavity and the external microresonator, it fails to describe the complicated nonlinear processes, especially for dark-pulse microcomb formation. Here, we investigate -- theoretically, numerically and experimentally -- the Kerr-thermal dynamics of a semiconductor laser self-injection-locked to an integrated silicon nitride microresonator. We unveil intriguing yet universal dark-pulse formation and switching behaviour with discrete steps, and establish a theoretical model scrutinizing the synergy of laser-microresonator mutual coupling, Kerr nonlinearity and photo-thermal effect. Numerical simulation confirms the experimental result and identifies the origins. Exploiting this unique phenomenon, we showcase an application on low-noise photonic microwave generation with phase noise purified by 23.5 dB. Our study not only adds critical insight of pulse formation in laser-microresonator hybrid systems, but also enables all-passive, photonic-chip-based microwave oscillators with high spectral purity.