Introducing a Symmetry-Breaking Coupler into a Dielectric Metasurface Enables Robust High-Q Quasibound States in the Continuum and Efficient Nonlinear Frequency Conversion

TL;DR

This paper introduces a symmetry-breaking coupler in dielectric metasurfaces to achieve high-Q quasi-BICs more robustly, enabling efficient nonlinear frequency conversion with relaxed fabrication constraints.

Contribution

A novel symmetry-breaking coupler design that relaxes fabrication precision requirements for high-Q quasi-BICs in dielectric metasurfaces.

Findings

High-Q resonances achieved with a large perturbative element at symmetry points.

Record-breaking second harmonic generation efficiencies >10^2 W^-1.

Robust high-Q quasi-BICs applicable to various geometries.

Abstract

Dielectric metasurfaces supporting quasi-bound states in the continuum (quasi-BICs) exhibit very high quality factor resonances and electric field confinement. However, accessing the high-Q end of the quasi-BIC regime usually requires marginally distorting the metasurface design from a BIC condition, pushing the needed nanoscale fabrication precision to the limit. This work introduces a novel concept for generating high-Q quasi-BICs, which strongly relaxes this requirement by incorporating a relatively large perturbative element close to high-symmetry points of an undistorted BIC metasurface, acting as a coupler to the radiation continuum. We validate this approach by adding a $\sim$100 nm diameter cylinder between two reflection-symmetry points separated by a 300 nm gap in an elliptical disk metasurface unit cell, using gallium phosphide as the dielectric. We find that high-Q resonances emerge when the cylindrical coupler is placed at any position between such symmetry points. We further explore this metasurface's second harmonic generation capability in the optical range. Displacing the coupler as much as a full diameter from a BIC condition produces record-breaking normalized conversion efficiencies >10$^{2}$ W$^{-1}$. The strategy of enclosing a disruptive element between multiple high-symmetry points in a BIC metasurface could be applied to construct robust high-Q quasi-BICs in many geometrical designs.