📝 SummarXiv

Abstract

Complex band structures describe resonant modes in periodic systems finite in one direction, crucial for applications in photonics like sensors and lasers. The imaginary frequency component, $\omega''$, tied to quality factors, is often probed through numerical or phenomenological models, limiting deeper insights. Here, we introduce a first-principles framework deriving complex band structures from scattering matrix poles, integrated with perturbation theory to define minimal Hilbert spaces based on interacting Bloch waves. Key results include a two-band model yielding $\omega'' = C(\mathbf{k}_{||})\delta^2$ and identifying accidental bound states in the continuum (BICs) at $C(\mathbf{k}_{||})=0$, with dual Fabry--P\'erot modes from impedance degeneracy; a three-band model reveals Friedrich--Wintgen and symmetry-protected BICs plus linewidth behaviors; inclusion of orthogonal polarizations characterizes far-field states and exceptional points; and the above model can be extended to two-dimensional systems. This unified approach advances light confinement studies, including nano-photonics and interdisciplinary wave physics with broad implications for high-performance optical devices.