Optimal light harvesting structures at optical and infrared frequencies

TL;DR

This paper develops design rules for optimizing one-dimensional nano-patterned light harvesting structures on metallic films to achieve high transmission efficiencies at optical and infrared frequencies, using both physical intuition and computational optimization.

Contribution

It introduces simple, effective design rules for slit-groove arrays that leverage mode hybridization, applicable across optical and infrared frequencies, and explores optimized nonuniform groove profiles.

Findings

Maximum transmission enhancement of 39% in optical frequencies.

Chirped groove profiles outperform uniform arrays.

Transmission enhancement decreases to 15% at infrared wavelengths.

Abstract

One-dimensional light harvesting structures with a realistic geometry nano-patterned on an opaque metallic film are optimized to render high transmission efficiencies at optical and infrared frequencies. Simple design rules are developed for the particular case of a slit-groove array with a given number of grooves that are symmetrically distributed with respect to a central slit. These rules take advantage of the hybridization of Fabry-Perot modes in the slit and surface modes of the corrugated metal surface. Same design rules apply for optical and infrared frequencies. The parameter space of the groove array is also examined with a conjugate gradient optimization algorithm that used as a seed the geometries optimized following physical intuition. Both uniform and nonuniform groove arrays are considered. The largest transmission enhancement, with respect to a uniform array, is obtained for a chirped groove profile. Such enhancement is a function of the wavelength. It decreases from 39% in the optical part of the spectrum to 15% at the long wavelength infrared.