posted on 2016-05-31, 00:00authored byJiaqi Li, Niels Verellen, Dries Vercruysse, Twan Bearda, Liesbet Lagae, Pol Van Dorpe
An
optical antenna forms the subwavelength bridge between free space
optical radiation and localized electromagnetic energy. Its localized
electromagnetic modes strongly depend on its geometry and material
composition. Here, we present the design and experimental realization
of a novel V-shaped all-dielectric antenna based on high-index amorphous
silicon with a strong magnetic dipole resonance in the visible range.
As a result, it exhibits extraordinary bidirectional scattering into
diametrically opposite directions. The scattering direction is effectively
controlled by the incident wavelength, rendering the antenna a passive
bidirectional wavelength router. A detailed multipole decomposition
analysis reveals that the excitation and abrupt phase change of an
out-of-plane polarized magnetic dipole and an in-plane electric quadrupole
are essential for the directivity switching. Previously, noble metals
have been extensively exploited for plasmonic directional nanoantenna
design. However, these inevitably suffer from high intrinsic ohmic
losses and a relatively weak magnetic response to the incident light.
Compared to a similar gold plasmonic nanoantenna design, we show that
the silicon-based antennas demonstrate stronger magnetic scattering
with minimal absorption losses. Our results indicate that all-dielectric
antennas will open exciting possibilities for efficient manipulation
of light-matter interactions.