Litcius/Paper detail

Quasi-normal mode theory of the scattering matrix, enforcing fundamental constraints for truncated expansions

Mohammed Benzaouia, John D. Joannopoulos, Steven G. Johnson, Aristeidis Karalis

2021Physical Review Research31 citationsDOIOpen Access PDF

Abstract

We develop a quasi-normal mode theory (QNMT) to calculate a system's scattering $S$ matrix, simultaneously satisfying both energy conservation and reciprocity even for a small truncated set of resonances. It is a practical reduced-order (few-parameter) model based on the resonant frequencies and constant mode-to-port coupling coefficients, easily computed from an eigensolver without the need for QNM normalization. Furthermore, we show how low-$Q$ modes can be separated into an effective slowly varying background response $C$, giving an additional approximate formula for $S$, which is useful to describe general Fano-resonant phenomena. We demonstrate our formulation for both normal and fixed-angle oblique plane-wave incidence on various electromagnetic metasurfaces.

Topics & Concepts

Reciprocity (cultural anthropology)PhysicsScatteringCoupling (piping)Mode (computer interface)Energy (signal processing)Normal modeSet (abstract data type)Conservation of energyMathematical analysisConstant (computer programming)Oblique caseCoupling constantMathematicsElectromagnetic theoryScattering theoryClassical mechanicsElectromagnetic fieldCoupled mode theoryQuantum electrodynamicsMode couplingElectromagnetic radiationRange (aeronautics)Quantum mechanicsMetamaterials and Metasurfaces ApplicationsElectromagnetic Scattering and AnalysisPlasmonic and Surface Plasmon Research