Abstract
Abstract All-dielectric nanoantennas, consisting of high refractive index semiconductor material, are drawing a great deal of attention in nanophotonics. Owing to their ability to manipulate efficiently the flow of light within sub-wavelength volumes, they have become the building blocks of a wide range of new photonic metamaterials and devices. The interaction of the antenna with light is largely governed by its size, geometry, and the symmetry of the multitude of optical cavity modes it supports. Already for simple antenna shapes, unraveling the full modal spectrum using conventional far-field techniques is nearly impossible due to the spatial and spectral overlap of the modes and their symmetry mismatch with incident radiation fields. This limitation can be circumvented by using localized excitation of the antenna. Here, we report on the experimental near-field probing of optical higher order cavity modes (CMs) and whispering gallery modes (WGMs) in amorphous silicon nanoantennas with simple, but fundamental, geometrical shapes of decreasing rotational symmetry: a disk, square, and triangle. Tapping into the near-field using an aperture type scanning near-field optical microscope (SNOM) opens a window on a rich variety of optical patterns resulting from the local excitation of antenna modes of different order with even and odd parity. Numerical analysis of the antenna and SNOM probe interaction shows how the near-field patterns reveal the node positions of – and allows us to distinguish between – cavity and whispering gallery modes. As such, this study contributes to a richer and deeper characterization of the structure of light in confined nanosystems, and their impact on the structuring of the light fields they generate.
Highlights
All-dielectric nanostructures are becoming key elements in modern nanophotonics R&D, allowing efficient control of the phase, polarization, and direction of light [1]
The full scanning near-field optical microscope (SNOM) map of each nanoantenna is obtained by scanning its surface with the probe in contact mode and recording the transmitted light intensity (T) collected by the objective lens shown at the bottom
The near-field distributions of the optical modes shown in the top row of panels (f–i) present finite-difference time-domain (FDTD) simulations of the dominant field component along z−direction at the wavelengths corresponding to Wa/W0 maxima
Summary
All-dielectric nanostructures are becoming key elements in modern nanophotonics R&D, allowing efficient control of the phase, polarization, and direction of light [1]. Such near-field studies have been performed on plasmonic nanoantennas of different shapes including disks, rods, triangles, Yagi-Uda antennas [46,47,48,49,50,51] and all-dielectric nanoantennas with, e.g., the visualization of electric quadrupole [52] and anapole [53, 54] modes in Si-nanodisks, and the magnetic field in the gap of Si-nanodisk dimers [55] Such a technique allows coupling only to a limited number of modes available for plane wave excitation, and tilted illumination should be used in order to access both even and odd parity modes. The wavelengths and probe positions that result in resonant excitation of the different modes can be identified by maxima of the electric field localization
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