Abstract
Controlling the directivity of emission and absorption at the nanoscale holds great promise for improving the performance of optoelectronic devices. Previously, directive structures have largely been centered in two categories—nanoscale antennas, and classical lenses. Herein, we utilize an evolutionary algorithm to design 3D dielectric nanophotonic lens structures leveraging both the interference-based control of antennas and the broadband operation of lenses. By sculpting the dielectric environment around an emitter, these nanolenses achieve directivities of 101 for point-sources, and 67 for finite-source nanowire emitters; 3× greater than that of a traditional spherical lens with nearly constant performance over a 200 nm wavelength range. The nanolenses are experimentally fabricated on GaAs nanowires, and characterized via photoluminescence Fourier microscopy, with an observed beaming half-angle of 3.5° and a measured directivity of 22. Simulations attribute the main limitation in the obtained directivity to imperfect alignment of the nanolens to the nanowire beneath.
Highlights
Controlling the directivity of emission and absorption at the nanoscale holds great promise for improving the performance of optoelectronic devices
Even within this search-space limitation, a huge number of spatial degrees of freedom can be optimized for nanophotonic lens design
Discussion the experimental results already show a great increase in directivity due to the nanolens, from 1.1 to 22.1 after application, it is instructive to understand the differences between the measurements and simulation in order to further improve future systems
Summary
Controlling the directivity of emission and absorption at the nanoscale holds great promise for improving the performance of optoelectronic devices. Micron-scale features are frequently employed to achieve efficient out-coupling for solid-state quantum light sources through a solid immersion lens[20,21,22,23], or can be used to create microlenses for directive emission[24,25,26,27] These structures are readily designed following a simple ray-tracing approach, considering that the features of the structure are at least on the order of many wavelengths, and their performance is fully determined by the size of the structure[28], as the wave nature of light is not utilized. These resulting structures appear unintuitive; their functionality is hard to predict given their shape, owing to the fact that for small spatial features light is dominated by its wave nature
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