# Chasing the thermodynamical noise limit in whispering-gallery-mode   resonators for ultrastable laser frequency stabilization

**Authors:** Jinkang Lim, Anatoliy A. Savchenkov, Elijah Dale, Wei Liang, Danny, Eliyahu, Vladimir Ilchenko, Andrey B. Matsko, Lute Maleki, and Chee Wei Wong

arXiv: 1701.05285 · 2017-08-23

## TL;DR

This paper demonstrates a WGM resonator-stabilized laser reaching the fundamental thermodynamical noise limit, achieving ultra-narrow linewidths and low Allan deviation, advancing miniaturized ultrastable laser technology.

## Contribution

It introduces a method to compensate thermal expansion in WGM resonators, enabling lasers at the thermodynamical noise limit with unprecedented stability.

## Key findings

- Achieved sub-25 Hz laser linewidth.
- Demonstrated 32 Hz Allan deviation at 191 THz.
- Identified environmental sensitivities at the thermodynamical noise limit.

## Abstract

Ultrastable high-spectral-purity lasers have served as the cornerstone behind optical atomic clocks, quantum measurements, precision optical-microwave generation, high resolution optical spectroscopy and sensing. Hertz-level lasers stabilized to high finesse Fabry-P\'erot mirror cavities are typically used for these studies but are large and fragile such that they have remained laboratory instruments. There is a clear demand in rugged miniaturized lasers operating potentially at comparable stabilities to those bulk lasers. Over the past decade, ultrahigh-Q optical whispering-gallery-mode (WGM) resonators have served as a platform for low-noise microlasers but have not yet reached the ultimate stabilities defined by their fundamental noise. Here, we show the noise characteristics of WGM resonators and demonstrate a resonator-stabilized laser at the fundamental limit by compensating the intrinsic thermal expansion of a WGM resonator, allowing a sub-25 Hz linewidth and a 32 Hz Allan deviation on the 191 THz carrier in 100 ms integration. We also reveal the environmental sensitivities of the resonator at the thermodynamical noise limit and long-term frequency drifts governed by random-walk-noise statistics.

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Source: https://tomesphere.com/paper/1701.05285