Broadband resonances in ITO nanorod arrays

TL;DR

This study investigates the waveguide resonances in ITO nanorod arrays, revealing their ability to strongly interact with light across a broad spectrum from visible to mid-infrared, with potential applications in photodetectors and solar cells.

Contribution

The paper provides a detailed analysis of the resonances in ITO nanorod arrays, distinguishing between visible and infrared resonances and developing simple analytical models for their spectral positions.

Findings

Nanorod arrays with 2.4% coverage strongly interact with light across a broad spectrum.

Resonances in visible are due to phase differences in guided waves, while infrared resonances are Fabry-Perot modes.

Analytical formulas accurately predict the spectral positions of the resonances.

Abstract

In the nanophotonics community, there is an active discussion regarding the origin of the selective absorption/scattering of light by the resonances with nanorod arrays. Here we report a study of the resonances in ordered indium-tin-oxide (ITO) nanorod arrays resulted from the waveguide modes. We discover that with only 2.4% geometrical coverage, the micron-length nanorod arrays strongly interact with light across an extra-wide band from visible to mid-infrared resulting in less than 10% transmission. Simulations show excellent agreement with our experimental observation. Near-field profile obtained from simulation reveals the electric field is mainly localized on the surfaces of the nanorods at all the resonances. Theoretical analysis is then applied to explain the resonances and it was found that the resonances in the visible are different from those in the infrared. When the light arrives at the array, part of the light wave propagates through the free space in between the nanorods and part of the wave is guided inside the nanorods and the phase difference at the ends of the rod interactions forms the basis of the resonances in the visible region; while the resonances in the infrared are Fabry-Perot resonances of the surface guided waves between the two ends of the nanorods. The simple analytical formulae developed predict the spectral positions of these resonances well. This information can be used to design devices like wavelength-selective photodetector, modulators, and nanorod-based solar cells.