dc.description.abstract | Nanophotonics allows the manipulation of light on the subwavelength scale. Optical
nanoantennas are nanoscale elements that enable increased resolution in bioimaging, novel
photon sources, solar cells with higher absorption, and the detection of fluorescence from a
single molecule. While plasmonic nanoantennas have been extensively explored in the literature,
dielectric nanoantennas have several advantages over their plasmonic counterparts, including
low dissipative losses and near-field enhancement of both electric and magnetic fields.
Nanoantennas increase the optical density of states, which increase the rate of spontaneous
emission due to the Purcell effect. The increase is quantified by the Purcell factor, which depends
on the mode volume and the quality factor. It is one of the main performance parameters for
nanoantennas. One particularly interesting feature of dielectric nanoantennas is the possibility of
integrating them into optical resonators with a high quality-factor, further improving the
performance of the nanoantennas and giving very high Purcell factors. This review introduces
the properties and parameters of dielectric optical nanoantennas, and gives a classification of the
nanoantennas based on the number and shape of the nanoantenna elements. An overview of
recent progress in the field is provided, and a simulation is included as an example. The
simulated nanoantenna, a dimer consisting of two silicon nanospheres separated by a gap, is
shown to have a very small mode volume, but a low quality-factor. Some recent works on
photonic crystal resonators are reviewed, including one that includes a nanoantenna in the bowtie
unit-cell. This results in an enormous increase in the calculated Purcell factor, from 200 for the
example dimer, to 8 × 10<sup>6</sup> for the photonic crystal resonator. Some applications of dielectric
nanoantennas are described. With current progress in the field, it is expected that the number of
applications will grow and that nanoantennas will be incorporated into new commercial
products. A list of relevant materials with high refractive indexes and low losses is presented and
discussed. Finally, prospects and major challenges for dielectric nanoantennas are addressed. | en_US |