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Polarization‐dependent mode coupling in hyperbolic nanospheres

Krzysztof M. Czajkowski, Maria Bancerek, Alexander Korneluk, Dominika Świtlik, Tomasz J. Antosiewicz

2021Nanophotonics11 citationsDOIOpen Access PDF

Abstract

Abstract Hyperbolic materials offer much wider freedom in designing optical properties of nanostructures than ones with isotropic and elliptical dispersion, both metallic or dielectric. Here, we present a detailed theoretical and numerical study on the unique optical properties of spherical nanoantennas composed of such materials. Hyperbolic nanospheres exhibit a rich modal structure that, depending on the polarization and direction of incident light, can exhibit either a full plasmonic‐like response with multiple electric resonances, a single, dominant electric dipole or one with mixed magnetic and electric modes with an atypical reversed modal order. We derive conditions for observing these resonances in the dipolar approximation and offer insight into how the modal response evolves with the size, material composition, and illumination. Specifically, the origin of the magnetic dipole mode lies in the hyperbolic dispersion and its existence is determined by two diagonal permittivity components of different sign. Our analysis shows that the origin of this unusual behavior stems from complex coupling between electric and magnetic multipoles, which leads to very strong scattering or absorbing modes. These observations assert that hyperbolic nanoantennas offer a promising route towards novel light–matter interaction regimes.

Topics & Concepts

PhysicsPolarization (electrochemistry)Mode couplingMagnetic dipoleCondensed matter physicsDipoleIsotropyCoupling (piping)PermittivityModalScatteringPlasmonNanostructureOpticsMetamaterialDispersion (optics)DiagonalMaterials sciencePolarization densityDielectricElectric fieldComputational physicsReciprocity (cultural anthropology)Light scatteringDiscrete dipole approximationClassical mechanicsElectric dipole momentNanophotonicsNormal modeInductive couplingSPHERESDegrees of freedom (physics and chemistry)Dispersion relationElectromagnetic radiationModal analysisCoupled mode theoryPurcell effectMagnetic dipole–dipole interactionMetamaterials and Metasurfaces ApplicationsPlasmonic and Surface Plasmon ResearchPhotonic Crystals and Applications
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