Engineered mode coupling in high-Q microresonators enables deterministic low-repetition-rate soliton microcombs

TL;DR

This paper demonstrates a novel method to generate low-repetition-rate soliton microcombs in high-Q microresonators by engineering mode coupling, overcoming thermal and coupling challenges in long cavities.

Contribution

It introduces a new approach using inter-modal coupling in racetrack microresonators to enable deterministic low-repetition-rate soliton microcombs.

Findings

Achieved thermally accessible single-soliton generation at 33 GHz.

Validated the approach in a high-Q silicon nitride microresonator.

Demonstrated robust and simple pathway for low-repetition-rate solitons.

Abstract

Soliton optical frequency combs have become key enablers for a wide range of applications, including telecommunications, optical atomic clocks, ultrafast distance measurements, dual-comb spectroscopy, and astrophysical spectrometer calibration, many of which benefit from low repetition rates. However, achieving such low-repetition-rate soliton microcombs is nontrivial as long cavities require substantially higher pump power, which induces stronger thermal effects that, in turn, exacerbate thermal instability and complicate access to stable soliton states. The dual-mode pumping scheme, in which a continuous-wave pump couples to both the comb-generating mode and an auxiliary mode, has proven simple and effective for mitigating thermal instability and enabling thermally accessible soliton generation. Yet, in long-cavity devices, the standard bus-to-resonator coupling conditions for these two modes diverge substantially, resulting in insufficient pump coupling to the auxiliary mode, which makes dual-mode pumping particularly challenging for low-repetition-rate microcombs. In this work, we overcome this limitation by coupling the pump to the auxiliary mode via inter-modal coupling, which can be introduced in racetrack microresonators and engineered by tailoring the cavity bend design. We validate this approach in a high-Q (>$10^7$) silicon nitride microresonator and demonstrate thermally accessible, deterministic single-soliton generation at a repetition rate of 33 GHz. This work provides a simple and robust pathway for generating low-repetition-rate soliton microcombs.