Optimization of wide-band quasi-omnidirectional 1-D photonic structures

TL;DR

This paper presents the design, fabrication, and characterization of wide-band quasi-omnidirectional multilayer photonic structures using chirping and stacking techniques, achieving high reflectance over broad spectral and angular ranges.

Contribution

It introduces novel multilayer design methods combining chirping and stacking to create thin, wide-band omnidirectional mirrors with optimized reflectance.

Findings

Achieved quasi-omnidirectional mirrors with bandwidths up to 1800 nm.

Demonstrated fabrication of structures with low refractive contrast materials.

Validated design predictions with experimental measurements.

Abstract

We have designed, optimized, fabricated and characterized highly reflective quasi-omnidirectional (angular range of $0-60^\circ$) multilayered structures with a wide spectral range. Two techniques, chirping (a continuous change in thicknesses) and stacking of Bragg-type sub-structures, have been used to enhance the reflectance with minimum thickness for a given pair of refractive indices. Numerical calculations were carried out employing the transfer matrix method and we optimized the design parameters to obtain maximal reflectance averaged over different spectral ranges for all angles. We fabricated some of the optimized structures with porous silicon dielectric multilayers with low refractive contrast and compared their measured optical properties with the calculations. Two chirped structures with thicknesses 21.6 $\mu$m and 60.4 $\mu$m, resulting in quasi omnidirectional mirrors with bandwidths of 360 nm and 1800 nm, centered at 1160 nm and 1925 nm respectively have been shown. In addition, we fabricated a stacked sub-Bragg mirror structure with a quasi omnidirectional bandwidth of 1800 nm (centered at 1850 nm) and a thickness of 41.5 $\mu$m, which is almost two third (in thickness) of the chirped structure. Thus, our techniques allowed us to obtain relatively thin quasi-omnidirectional mirrors with wide bands over different wavelength ranges. Our analysis techniques can be used for the optimization of the reflectance not only in multilayered PS systems with different refractive index contrasts but also for systems with other types of materials with low refractive index contrast. The present study could also be useful for obtaining omnidirectional dielectric mirrors in large spectral regions using different materials, flat focusing reflectors, thermal regulators, or, if defects are included, as filters or remote chemical/biosensors with a wide angular independent response.