Litcius/Paper detail

Fundamental Thermal Noise Limits for Optical Microcavities

Christopher Panuski, Dirk Englund, Ryan Hamerly

2020Physical Review X29 citationsDOIOpen Access PDF

Abstract

We present a joint theoretical and experimental analysis of thermorefractive noise in high-quality-factor (Q), small-mode-volume (V) optical microcavities. Analogous to well-studied stability limits imposed by Brownian motion in macroscopic Fabry-Perot resonators, we show that microcavity thermorefractive noise gives rise to a mode-volume-dependent maximum effective quality factor. State-of-the-art fabricated microcavities are found to be within one order of magnitude of this bound. By measuring the first thermodynamically limited frequency noise spectra of wavelength-scale high-Q=V silicon photonic crystal cavities, we confirm the assumptions of our theory, demonstrate a broadband sub-K= ffiffiffiffiffiffi Hz p temperature sensitivity, and unveil a new technique for discerning subwavelength changes in microcavity mode volumes. To illustrate the immediate implications of these results, we show that thermorefractive noise limits the optimal performance of recently proposed room-temperature, all-optical qubits using cavityenhanced bulk material nonlinearities. Looking forward, we propose and analyze coherent thermo-optic noise cancellation as one potential avenue toward violating these bounds, thereby enabling continued development in quantum optical measurement, precision sensing, and low-noise integrated photonics.

Topics & Concepts

Noise (video)PhysicsBroadbandQuantum noiseQubitBrownian motionOptical microcavityOpticsQuantumPhotonicsQuality (philosophy)ThermalThermal fluctuationsOptoelectronicsStability (learning theory)Photonic crystalQuantum opticsBrownian noiseLaser linewidthOptomechanicsMode (computer interface)ResonatorFlicker noiseQuantum dotNoise floorBackground noiseStrong Light-Matter InteractionsPhotonic Crystals and ApplicationsMechanical and Optical Resonators