Cellulose-Based Reflective Liquid Crystal Films as Optical Filters and Solar Gain Regulators

TL;DR

This paper presents cellulose nanocrystal-based films with helicoidal structures that mimic natural reflectors, exhibiting tunable high reflectivity in visible and near-infrared spectra for optical filtering and solar regulation.

Contribution

It introduces a self-assembly method for creating cellulose nanocrystal films with natural-like reflective properties for optical and energy applications.

Findings

Films exhibit high reflectivity tunable in visible and near-infrared spectra.

Films mimic natural polarization-insensitive reflectors.

Potential applications include color filters and solar gain regulation.

Abstract

Many promising approaches for designing interactions of synthetic materials with light involve solid optical monocrystals and nanofabricated photonic crystal structures with spatially periodic variations of refractive index. Although their high costs limit current technological applications, remarkably, such photonic and optically anisotropic materials have also evolved throughout nature and enable narrow or broad-band spectral reflection of light. Here we use self-assembly of biomaterial cellulose nanocrystals to obtain three-layer films with helicoidal and nematic-like organization of the cellulose nanoparticles, which mimics naturally occurring polarization-insensitive reflectors found in the wings of Plusiotis resplendens beetles. These films were characterized with polarized optical microscopy and circular dichroism spectrometry, as well as scanning and transmission electron microscopies. These films exhibit high reflectivity tunable within the visible and near-infrared regions of the optical spectrum and may find applications ranging from color filters to smart cloth designs and in solar-gain-regulating building technologies.