Degenerate merging BICs in resonant metasurfaces

TL;DR

This paper demonstrates how merging bound states in the continuum (BICs) in resonant metasurfaces can create degenerate BICs with suppressed radiation losses, enabling enhanced high-Q resonances for light-matter interactions.

Contribution

It introduces a method to achieve degenerate merging BICs in metasurfaces by tuning parameters, leading to new control over resonance properties.

Findings

Degenerate merging BICs can be realized in metasurfaces through parametric tuning.

Merging BICs can be split or annihilated by adjusting lattice constants or thickness.

The phenomenon is explained by interactions between GMRs and Fabry-Perot resonances.

Abstract

Resonant metasurfaces driven by bound states in the continuum (BIC) offer an intriguing approach to engineer high-Q resonances. Merging multiple BICs in the momentum space could further enhance the Q-factor as well as its robustness to fabrication imperfections. Here, we report doubly-degenerate guided mode resonances (GMR) in a resonant metasurface, whose radiation losses could be totally suppressed due to merging BICs. We show that the GMRs and their associated accidental BICs can be evolved into degenerate merging BICs by parametric tuning of the metasurface. Significantly, these two GMRs share the same critical parameter (i.e. lattice constants or thickness) that the merging BICs occur. Interestingly, thanks to the degenerate property of two GMRs, a larger (smaller) period will split one of merging BICs into eight accidental BICs at off-{\Gamma} point, but annihilate the other. Such exotic phenomenon can be well explained from the interaction of GMRs and background Fabry-Perot resonances. Our result provides new strategies to engineering high-Q resonances in resonant metasurfaces for light-matter interaction.