Ultrastable nanophotonic microcavities via integrated thermometry

Abstract: Integrated photonic devices that can be co-packaged with electronics and can operate in real-world environments will enable many important applications, such as optical interconnects, quantum information processing, precision measurements, spectroscopy, and microwave generation. Significant progress has been made over the past two decades on increasing the functional complexity of photonic chips. However, the most critical challenge that remains is the lack of scalable techniques to overcome perturbations arising from environmental thermal noise and thermal crosstalk from co-packaged electronics and other photonic devices sharing the same substrate. Here, we propose and demonstrate a fully-integrated scheme to monitor and stabilize the temperature of a high-Q microresonator in a Si-based chip. We show that when stabilized, the microresonator exhibits remarkable resilience against external thermal noise and can serve as a fully-integrated photonic frequency reference. By simply changing the temperature set-point, the cavity resonance frequency can be repeatably tuned without any hysteresis over several hours. We also show that the frequency of a distributed feedback (DFB) laser can be stabilized to this microresonator and realize a 48 dB reduction in its frequency drift, resulting in its center wavelength staying within +-0.5 pm of the mean over the duration of 50 hours in the presence of significant ambient fluctuations. This performance is superior to many commercial DFB systems and is highly suitable for use in data-communication systems. Finally, we demonstrate that the technique can be implemented to stabilize a soliton modelocked Kerr comb against significant ambient and crosstalk thermal noise, without the need for photodetection, paving the way for Kerr-comb-based photonic devices that can operate in the desired modelocked state indefinitely.