Angle‐, Polarization‐, and Wavelength‐Resolved Light Scattering of Single Mie Resonators Using Fourier‐Plane Spectroscopy
Tatsuki Hinamoto, Mikihiko Hamada, Hiroshi Sugimoto, Minoru Fujii
Abstract
Abstract Interference between multipole modes of Mie resonance provides the possibility to tailor a radiation pattern of a subwavelength optical resonator. Unidirectional scattering arising from constructive and destructive interferences between electric and magnetic dipolar modes in a nanoantenna allows to design a variety of metasurfaces. However, experimental determination of radiation patterns of an individual nanoobject and the decomposition into multipoles have not been performed under plane wave illumination due to the inability of angular analysis in a conventional optical microscope. To this end, an angle‐, polarization‐, and wavelength‐resolved microscopy setup is developed in this work to measure radiation patterns of an individual nanoobject. A single spherical silicon nanosphere is employed as an ideal Mie resonator and the angle‐ and polarization‐resolved scattering is measured in the angular range from 30° to 150° against the incident angle. It is shown that Mie scattering from the electric and magnetic dipoles of a single silicon nanosphere is selectively measured in the setup.