Abstract
Microresonator frequency combs can be an enabling technology for optical frequency synthesis and timekeeping in low size, weight, and power architectures. Such systems require comb operation in low-noise, phase-coherent states such as solitons, with broad spectral bandwidths (e.g., octave-spanning) for self-referencing to detect the carrier-envelope offset frequency. However, accessing such states is complicated by thermo-optic dispersion. For example, in the Si3N4 platform, precisely dispersion-engineered structures can support broadband operation, but microsecond thermal time constants often require fast pump power or frequency control to stabilize the solitons. In contrast, here we consider how broadband soliton states can be accessed with simple pump laser frequency tuning, at a rate much slower than the thermal dynamics. We demonstrate octave-spanning soliton frequency combs in Si3N4 microresonators, including the generation of a multi-soliton state with a pump power near 40 mW and a single-soliton state with a pump power near 120 mW. We also develop a simplified two-step analysis to explain how these states are accessed without fast control of the pump laser, and outline the required thermal properties for such operation. Our model agrees with experimental results as well as numerical simulations based on a Lugiato-Lefever equation that incorporates thermo-optic dispersion. Moreover, it also explains an experimental observation that a member of an adjacent mode family on the red-detuned side of the pump mode can mitigate the thermal requirements for accessing soliton states.
Highlights
Soliton states in Kerr microcavities represent a path to low-noise comb formation with properties suitable for metrological applications [1, 2], including optical frequency synthesis [3, 4], optical clocks [5, 6], microwave generation [7, 8], etc
To better understand our system, we present a simplified analysis to systematically study the thermal accessability of the available soliton states for the given scanning parameters, and the results agree with the experimental data and full numerical simulations that consider both the Kerr and thermal effects
Our soliton microcomb states can be accessed with slow frequency tuning of the pump laser, relinquishing the need for more complicated control of pump power and/or frequency
Summary
Soliton states in Kerr microcavities represent a path to low-noise comb formation with properties suitable for metrological applications [1, 2], including optical frequency synthesis [3, 4], optical clocks [5, 6], microwave generation [7, 8], etc. To better understand our system, we present a simplified analysis to systematically study the thermal accessability of the available soliton states for the given scanning parameters, and the results agree with the experimental data and full numerical simulations that consider both the Kerr and thermal effects. This method allows us to explain an interesting experimental observation that an adjacent mode family member on the red-detuned side of the pump resonance helps stabilize the thermal dynamics during soliton formation, which represents a novel means to generate solitons with slow pump frequency tuning and without a significant improvement to the resonator quality factor, absorption rate, or thermal conductance
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