Synthetic five-wave mixing in an integrated microcavity for visible-telecom entanglement generation

TL;DR

This paper demonstrates the first synthesis of a five-wave mixing process ($ ext{chi}^{(4)}$) in a microcavity by combining $ ext{chi}^{(2)}$ and $ ext{chi}^{(3)}$ nonlinearities, enabling efficient visible-telecom photon pair generation.

Contribution

It introduces a novel method of creating high-order nonlinearities through photonic structure engineering, bypassing the need for new materials.

Findings

Synthetic five-wave mixing achieved in a microcavity.

Photon pair generation rate enhanced over 500 times.

Verified coherence via entangled photon pairs.

Abstract

Nonlinear optics processes lie at the heart of photonics and quantum optics for their indispensable role in light sources and information processing. During the past decades, the three- and four-wave mixing ($\chi^{(2)}$ and $\chi^{(3)}$) effects have been extensively studied, especially in the micro-/nano-structures by which the photon-photon interaction strength is greatly enhanced. So far, the high-order nonlinearity beyond the $\chi^{(3)}$ has rarely been studied in dielectric materials due to their weak intrinsic nonlinear susceptibility, even in high-quality microcavities. Here, an effective five-wave mixing process ($\chi^{(4)}$) is synthesized for the first time, by incorporating $\chi^{(2)}$ and $\chi^{(3)}$ processes in a single microcavity. The coherence of the synthetic $\chi^{(4)}$ is verified by generating time-energy entangled visible-telecom photon-pairs, which requires only one drive laser at the telecom waveband. The photon pair generation rate from the synthetic process shows an enhancement factor over $500$ times upon intrinsic five-wave mixing. Our work demonstrates a universal approach of nonlinear synthesis via photonic structure engineering at the mesoscopic scale rather than material engineering, and thus opens a new avenue for realizing high-order optical nonlinearities and exploring novel functional photonic devices.