AI Article Synopsis
- The study focuses on enhancing directional scattering from optical nanoantennas, which is crucial for applications in photovoltaics and integrated light sources.
- A design based on the interference of electric dipoles using two coupled rectangular nanoparticles (dimers) is proposed to achieve this directional scattering through plasmonic geometries.
- The effectiveness of this approach relies on optimizing the size and phase relation of the nanoparticles to enable robust and broadband scattering, even when arranged in an array, as long as interference does not block the preferred scattering direction.
Article Abstract
Strong and directionally specific forward scattering from optical nanoantennas is of utmost importance for various applications in the broader context of photovoltaics and integrated light sources. Here, we outline a simple yet powerful design principle to perceive a nanoantenna that provides directional scattering into a higher index substrate based on the interference of multiple electric dipoles. A structural implementation of the electric dipole distribution is possible using plasmonic nanoparticles with a fairly simple geometry, i.e. two coupled rectangular nanoparticles, forming a dimer, on top of a substrate. The key to achieve directionality is to choose a sufficiently large size for the nanoparticles. This promotes the excitation of vertical electric dipole moments due to the bi-anisotropy of the nanoantenna. In turn, asymmetric scattering is obtained by ensuring the appropriate phase relation between the vertical electric dipole moments. The scattering strength and angular spread for an optimized nanoantenna can be shown to be broadband and robust against changes in the incidence angle. The scattering directionality is maintained even for an array configuration of the dimer. It only requires the preferred scattering direction of the isolated nanoantenna not to be prohibited by interference.
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| http://dx.doi.org/10.1364/OE.24.019638 | DOI Listing |
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