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Plasmonic metasurfaces for efficient phase control in reflection.

Anders Pors, Sergey I Bozhevolnyi

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    This study explores metal-insulator-metal resonators and metasurfaces, focusing on gap-surface plasmon resonances. Researchers demonstrate precise control over light polarization for advanced optical devices like gradient metasurfaces.

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    Area of Science:

    • Nanophotonics
    • Plasmonics
    • Metamaterials

    Background:

    • Metal-insulator-metal (MIM) structures support gap-surface plasmon (GSP) resonances.
    • Metasurfaces offer tailored control over light polarization and phase.

    Purpose of the Study:

    • To numerically investigate the optical properties of MIM resonators and metasurfaces.
    • To explore the role of GSP resonances in optical response.
    • To demonstrate simultaneous phase control for orthogonal polarizations using nanobrick and nanocross elements.

    Main Methods:

    • Numerical simulations of optical properties.
    • Design and analysis of metal-backed metasurfaces with nanobrick and nanocross elements.
    • Investigation of gap-surface plasmon (GSP) resonances.

    Main Results:

    • Established a connection between GSP resonances and optical response.
    • Demonstrated full phase control for two orthogonal polarizations simultaneously.
    • Designed a gradient birefringent metasurface achieving ~80% reflectivity for specific diffraction orders (+2 and -3) around 800 nm.
    • Introduced the concept of metascatterers (wavelength-sized polarization-sensitive scatterers).

    Conclusions:

    • Metal nanobrick and nanocross elements provide versatile control over light polarization.
    • Gradient birefringent metasurfaces can achieve high reflectivity and precise beam steering.
    • Metascatterers represent a novel approach for polarization-sensitive light manipulation.