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Dynamically tunable and ultrastable plasmonic bound states in the continuum in bilayer graphene metagratings

Jiali Huang, Guizi Qing, Di Zhang, Xiang Zhai, Jun Peng, Sheng-Xuan Xia

2025Physical review. B./Physical review. B17 citationsDOI

Abstract

Bound states in the continuum (BICs), a universal wave phenomenon observed in plasmonic and other wave systems, remain spatially localized despite coexisting with a radiative continuum. However, current implementations of plasmonic BICs (pBICs) suffer from critical limitations: lack of dynamic tunability or poor stability in key parameters such as resonance wavelengths and quality factors (Q factors). In this paper, we propose a bilayer graphene metagrating with sinusoidal periodic conductivity modulation to address these challenges. We demonstrate two independent pBICs with quantized topological charge (\ensuremath{-}1, confirmed via momentum-space polarization singularities), emerging under in-phase and out-of-phase conductivity configurations. Remarkably, owing to the invariant coupling strength under arbitrary lateral offsets of interlayer conductivity patterns, these pBICs exhibit ultralow variance in both wavelengths and Q factors within a particular range of asymmetry parameters, ensuring unprecedented spectral stability under perturbations. The proposed metagrating architecture enables high-performance refractive index sensing and dual-mode perfect absorption, offering a robust platform for actively tunable pBIC devices with tailored spectral and topological functionalities.

Topics & Concepts

PlasmonPolarization (electrochemistry)Optical conductivityGrapheneOptoelectronicsMaterials scienceAsymmetryConductivityJanusCondensed matter physicsWavelengthBilayer grapheneSpectral asymmetryRefractive indexPhysicsBound stateTopology (electrical circuits)MetamaterialBilayerCoupling (piping)Coupled mode theoryNanoscopic scaleConductanceAmplitude modulationNanophotonicsStability (learning theory)Fano resonanceElectrical impedanceResonance (particle physics)Mode couplingCharge (physics)InstabilityQuality (philosophy)Plasmonic and Surface Plasmon ResearchMetamaterials and Metasurfaces ApplicationsTopological Materials and Phenomena
Dynamically tunable and ultrastable plasmonic bound states in the continuum in bilayer graphene metagratings | Litcius