Linear arrays of noble metal nanoparticles, supporting Bragg plasmonic resonances, are proposed as optical nanoantennae. Electrodynamic calculations show that tunable, directional and wavelength selective emission enhancement is obtained throughout the visible and near-infrared spectrum by varying the dielectric environment and the array geometrical parameters, and thus tuning the Bragg modes. Large quantum efficiency enhancements are possible even in the case of poor emitters ( 1% intrinsic efficiency), spanning wavelengths that are relevant in lighting (lambda similar or equal to 400 nm) and telecommunication (lambda similar or equal to 1.5 mu m) applications. Nanoantenna array angular emission is highly directional and extremely sensitive to the array geometrical parameters and the dielectric environment.
Tunable, directional and wavelength selective plasmonic nanoantenna arrays
PELLEGRINI, GIOVANNI;MATTEI, GIOVANNI;MAZZOLDI, PAOLO
2009
Abstract
Linear arrays of noble metal nanoparticles, supporting Bragg plasmonic resonances, are proposed as optical nanoantennae. Electrodynamic calculations show that tunable, directional and wavelength selective emission enhancement is obtained throughout the visible and near-infrared spectrum by varying the dielectric environment and the array geometrical parameters, and thus tuning the Bragg modes. Large quantum efficiency enhancements are possible even in the case of poor emitters ( 1% intrinsic efficiency), spanning wavelengths that are relevant in lighting (lambda similar or equal to 400 nm) and telecommunication (lambda similar or equal to 1.5 mu m) applications. Nanoantenna array angular emission is highly directional and extremely sensitive to the array geometrical parameters and the dielectric environment.Pubblicazioni consigliate
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