Accidental and symmetry-protected bound states in the continuum in planar photonic-crystal structures, studied by the resonant-state expansion

TL;DR

This paper demonstrates the application of the resonant-state expansion method to accurately identify and analyze bound states in the continuum within photonic crystal slabs, distinguishing between accidental and symmetry-protected types.

Contribution

The study introduces the RSE as an efficient tool for finding and understanding BICs in photonic structures, including their formation and evolution.

Findings

RSE reliably identifies BICs in photonic crystal slabs.

It differentiates between accidental and symmetry-protected BICs.

The method efficiently explores the full parameter space.

Abstract

The resonant-state expansion (RSE) provides a precise and computationally cheap tool to find resonant states in complex systems using the optical modes of a simpler system as a basis. We apply the RSE to a photonic crystal slab in order to identify and analyze its bound states in the continuum (BICs). We show that the RSE is a useful and reliable method for not only finding the BICs but also for differentiating between accidental and symmetry-protected BICs, as well as for understanding their formation from the basis modes and evolution with structural and material parameters of the system. The high efficiency of the RSE allows us to track the properties of BICs and other high-quality optical modes, covering the full parameter space of the system in a reasonable time frame.