Mathematical Analysis of Symmetry-Protected Bound States in the Continuum in Waveguide Arrays

TL;DR

This paper provides a rigorous mathematical framework for analyzing symmetry-protected Bound States in the Continuum in finite and infinite optical waveguide arrays, including proofs of existence and numerical demonstrations of mode transitions.

Contribution

It introduces a novel nonorthogonal coupled-mode model and offers exact expressions for coupling coefficients, advancing the theoretical understanding of BICs in waveguide systems.

Findings

Exact expressions for overlap integrals and coupling coefficients.

Proof of BIC existence in symmetric waveguide configurations.

Numerical demonstration of BIC to leaky mode transition.

Abstract

This paper presents a rigorous mathematical analysis for symmetry-based Bound States in the Continuum (BICs) in optical waveguide arrays. Different from existing research, we consider a finite system of horizontally and equidistantly aligned waveguides and transform the wave propagation problem into Nonorthogonal Coupled-Mode Equations (NCME), rather than adopting the tight-binding approximation or orthogonal coupled-mode equations. We derive the exact expressions of the overlap integrals and coupling coefficients by utilizing the addition theorems of Bessel functions. We then generalize the discussion to an infinite waveguide array and rigorously characterize the dispersion relation and continuum with the help of theories in harmonic analysis. In the second part of the paper, we give a strict proof of the existence of BICs in the aforementioned waveguide system with two additional identical vertical waveguides aligned symmetrically above and below the horizontal waveguide array. We further numerically demonstrate the transition from a perfect BIC to a leaky mode by introducing a symmetry-breaking refractive index perturbation and quantitatively analyze the resulting radiation losses. This work gives a comprehensive study of symmetry-protected BICs and provides an efficient and precise computational model for designing such BICs devices.