Chip-scale modulation-free laser stabilization using vacuum-gap micro-Fabry-P\'erot cavity
Abstract
Narrow-linewidth lasers are vital for a broad range of scientific and technological applications, including atomic clocks and precision sensing. Achieving high frequency stability is often as critical as ensuring scalability, portability, and cost-effectiveness in the development of low noise laser systems. Conventional electro-optic stabilization techniques, such as Pound-Drever-Hall locking to ultra-high-finesse resonators held in a vacuum chamber, provide excellent performance but remain challenging to scale. Here, we propose and experimentally demonstrate a cavity-coupled interferometric laser stabilization technique implemented on a silicon photonic chip and integrated with a compact, scalable micro-Fabry-P\'erot cavity. The vacuum-gap optical cavity operates in air, achieving a quality factor of approximately and a fractional frequency instability of at one-second averaging time. Integration of the proposed technique with the compact cavity yields more than 38-fold reduction in the laser's integrated linewidth and nearly three orders of magnitude suppression of frequency noise at 10 Hz offset frequency. The hybrid-integration of the proposed photonic chip with the micro-Fabry-P\'erot cavity establishes a scalable and portable route toward chip-integrated ultra-stable lasers, paving the way for precision optical systems deployable beyond laboratory environments.
Keywords
Cite
@article{arxiv.2510.21565,
title = {Chip-scale modulation-free laser stabilization using vacuum-gap micro-Fabry-P\'erot cavity},
author = {Mohamad Hossein Idjadi and Haotian Cheng and Farshid Ashtiani and Benjia Li and Kwangwoong Kim and Naijun Jin and Franklyn Quinlan and Peter T. Rakich},
journal= {arXiv preprint arXiv:2510.21565},
year = {2025}
}
Comments
16 pages and 4 figures (main manuscript), 6 pages and 3 figures (supplementary document)