High-Q two-dimensional lithium niobate photonic crystal slab nanoresonators

TL;DR

This paper reports the development of high-Q two-dimensional lithium niobate photonic crystal slab nanoresonators with unprecedented optical quality, enabling new nonlinear optical phenomena and advancing integrated photonic circuits.

Contribution

Demonstrated the first high-Q 2D lithium niobate photonic crystal slab nanoresonators with Q as high as 3.51×10^5, revealing novel anisotropic nonlinear optical effects.

Findings

Achieved ultra-high optical Q of 3.51×10^5 in 2D LN PhC nanoresonators

First observation of third harmonic generation in on-chip LN nanophotonics

Detected strong orientation-dependent second harmonic generation

Abstract

Lithium niobate (LN), known as "silicon of photonics," exhibits outstanding material characteristics with great potential for broad applications. Enhancing light-matter interaction in the nanoscopic scale would result in intriguing device characteristics that enable revealing new physical phenomena and realizing novel functionalities inaccessible by conventional means. High-Q two dimensional (2D) photonic crystal (PhC) slab nanoresonators are particularly suitable for this purpose, which, however, remains open challenge to be realized on the lithium niobate platform. Here we take an important step towards this direction, demonstrating 2D LN PhC slab nanoresonators with optical Q as high as $3.51 \times 10^5$, about three orders of magnitude higher than other 2D LN PhC structures reported to date. The high optical quality, tight mode confinement, together with pure polarization characteristics of the devices enable us to reveal peculiar anisotropy of photorefraction quenching and unique anisotropic thermo-optic nonlinear response, which have never been reported before. They also allow us to observe third harmonic generation for the first time in on-chip LN nanophotonic devices, and strong orientation-dependent generation of second harmonic. The demonstrated high-Q 2D LN PhC nanoresonators not only offer an excellent device platform for the exploration of extreme nonlinear and quantum optics at single-photon and few-photon level, but also open up a great avenue towards future development of large-scale integrated LN photonic circuits for energy efficient nonlinear photonic and electro-optic signal processing.