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Linear optical elements based on cooperative subwavelength emitter arrays.

Nico S Baßler, Michael Reitz, Kai Phillip Schmidt

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    |February 24, 2023
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    Summary
    This summary is machine-generated.

    Two-dimensional quantum emitter arrays act as efficient optical elements. These arrays control light transmission and polarization using emitter interactions and magnetic fields.

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    Area of Science:

    • Quantum optics
    • Nanophotonics
    • Metamaterials

    Background:

    • Subwavelength quantum emitter arrays offer novel optical functionalities.
    • Controlling light-matter interactions at the nanoscale is crucial for advanced optical devices.

    Purpose of the Study:

    • To explore the use of 2D subwavelength quantum emitter arrays as efficient optical elements.
    • To demonstrate the control over optical properties like transmission, resonance frequency, and bandwidth.
    • To engineer polarization control elements such as polarizers and phase retarders.

    Main Methods:

    • Analytical modeling of cooperative optical response due to dipole-dipole interactions.
    • Numerical simulations to validate analytical predictions.
    • Description of optical operations using Jones matrices.
    • Investigation of the role of array geometry and external magnetic fields.

    Main Results:

    • Cooperative optical response enables control over array transmission, resonance frequency, and bandwidth for normally incident light.
    • Engineered linear and circular polarizers and phase retarders for polarized light.
    • Identified optimal operating regimes through analytical and numerical approaches.
    • Highlighted the significance of array geometry and magnetic field tuning.

    Conclusions:

    • Two-dimensional quantum emitter arrays are versatile optical elements.
    • Precise control over optical properties is achievable by tuning array geometry and magnetic fields.
    • These arrays hold promise for developing advanced polarization optics and optical switches.