English

Squeezed light from a nanophotonic molecule

Optics 2021-04-28 v2 Quantum Physics

Abstract

Photonic molecules are composed of two or more optical resonators, arranged such that some of the modes of each resonator are coupled to those of the other. Such structures have been used for emulating the behaviour of two-level systems, lasing, and on-demand optical storage and retrieval. Coupled resonators have also been used for dispersion engineering of integrated devices, enhancing their performance for nonlinear optical applications. Delicate engineering of such integrated nonlinear structures is required for developing scalable sources of non-classical light to be deployed in quantum information processing systems. In this work, we demonstrate a photonic molecule composed of two coupled microring resonators on an integrated nanophotonic chip, designed to generate strongly squeezed light uncontaminated by noise from unwanted parasitic nonlinear processes. By tuning the photonic molecule to selectively couple and thus hybridize only the modes involved in the unwanted processes, suppression of parasitic parametric fluorescence is accomplished. This strategy enables the use of microring resonators for the efficient generation of degenerate squeezed light: without it, simple single-resonator structures cannot avoid contamination from nonlinear noise without significantly compromising pump power efficiency, and are thus limited to generating only weak degenerate squeezing. We use this device to generate 8(1) dB of broadband degenerate squeezed light on-chip, with 1.65(1) dB directly measured, which is the largest amount of squeezing yet reported from any nanophotonic source.

Keywords

Cite

@article{arxiv.2001.09474,
  title  = {Squeezed light from a nanophotonic molecule},
  author = {Y. Zhang and M. Menotti and K. Tan and V. D. Vaidya and D. H. Mahler and L. G. Helt and L. Zatti and M. Liscidini and B. Morrison and Z. Vernon},
  journal= {arXiv preprint arXiv:2001.09474},
  year   = {2021}
}

Comments

Significantly updated: improved data, results, and experimental details

R2 v1 2026-06-23T13:20:56.178Z