{\mu}W-Level Microresonator Solitons with Extended Stability Range Using an Auxiliary Laser

TL;DR

This paper demonstrates a passive stabilization method using an auxiliary laser to significantly extend the stability range of microresonator solitons, enabling low-power, robust soliton generation with relaxed laser stability requirements.

Contribution

The authors introduce a passive stabilization technique with an auxiliary laser that greatly increases the stability range of microresonator solitons, simplifying their generation process.

Findings

Extended soliton stability range by two orders of magnitude.

Achieved soliton generation at power levels below 3 mW.

Demonstrated soliton generation at 780 μW threshold power.

Abstract

The recent demonstration of dissipative Kerr solitons in microresonators has opened a new pathway for the generation of ultrashort pulses and low-noise frequency combs with gigahertz to terahertz repetition rates, enabling applications in frequency metrology, astronomy, optical coherent communications, and laser-based ranging. A main challenge for soliton generation, in particular in ultra-high-Q resonators, is the sudden change of circulating intracavity power during the onset of soliton generation. This sudden power change requires precise control of the seed laser frequency and power or fast control of the resonator temperature. Here, we report a robust and simple way to increase the stability range of the soliton regime by using an auxiliary laser that passively stabilizes the intracavity power. In our experiments with fused silica resonators, we are able to extend the pump laser frequency stability range of microresonator solitons by two orders of magnitude, which enables soliton generation by slow and manual tuning of the pump laser into resonance and at unprecedented low power levels. Both single- and multi-soliton mode-locked states are generated in a 1.3-mm-diameter fused silica microrod resonator with a free spectral range of ~50.6 GHz, at a 1554 nm pump wavelength at threshold powers <3 mW. Moreover, with a smaller 230-{\mu}m-diameter microrod, we demonstrate soliton generation at 780 {\mu}W threshold power. The passive enhancement of the stability range of microresonator solitons paves the way for robust and low threshold microcomb systems with substantially relaxed stability requirements for the pump laser source. In addition, this method could be useful in a wider range of microresonator applications that require reduced sensitivity to external perturbations.