Integrated Architecture for the Automated Generation and Coil Stabilization of a PZT-Enabled Microcomb

Abstract: Silicon nitride Dissipative Kerr Soliton (DKS) microcombs have emerged as a future solution to bring metrological optical frequency comb capabilities into a photonic integrated platform with mass-scale fabrication benefits. Precision applications demand low comb line phase noise as well as high repetition rate stability, but current approaches to achieve this involve complex architectures, multiple lasers, and high-power components, which are challenging to integrate to the chip scale. To achieve this goal, new architectures are needed to simplify the comb generation, actuation, and pump laser requirements, while enabling chip-integrated solutions. Here we demonstrate a greatly simplified stabilized DKS comb architecture with a single laser and a single point electronic control of both the microcomb generation and its stabilization to a coil-resonator reference. The silicon nitride microcomb is integrated with a low power, broadband PZT actuator that is driven by a simple electronic control sequence that generates a soliton and stabilizes it to the 16-meter silicon nitride coil resonator. PZT-enabled control brings flexibility and simplicity to the soliton generation and stabilization using a single CW pump laser, resulting in significantly reduced electronic and optical infrastructure. We demonstrate coil-resonator locking which suppresses the 1 kHz frequency noise by 40 dB over the 35 nm wide comb spectrum, with comb line linewidths as low as 66 Hz and 108 GHz soliton repetition rate phase noise equivalent to -118 dBc/Hz when divided down to 10 GHz. The low power PZT actuator consumes nW bias power and the coil resonator allows flexible dual locking using arbitrary comb lines. These results show a clear path towards full chip integration of stabilized soliton microcombs with simplicity and versatility absent in other schemes.