Enhanced light absorption in all-polymer biomimetic photonic structures by near-zero-index organic matter

TL;DR

This paper demonstrates that combining near-zero index organic materials into multilayer photonic structures enhances broadband light absorption, slow light effects, and tunable optical properties, advancing all-polymer photonic device development.

Contribution

It introduces a novel approach using NZI organic thin films in multilayer structures to achieve tunable broadband optical effects in the visible spectrum.

Findings

Broadband tunable strong reflectance achieved

Enhanced slow light absorption in the visible range

Photoluminescence properties can be tailored

Abstract

Natural photosynthetic photonic nanostructures can show sophisticated light matter-interactions including enhanced light absorption by slow light even for highly pigmented systems. Beyond fundamental biology aspects these natural nanostructures are very attractive as blueprints for advanced photonic devices. But the soft-matter biomimetic implementations of such nanostructures is challenging due to the low refractive index contrast of most organic photonic structures. Excitonic organic material with near zero index (NZI) optical properties allow overcoming these bottlenecks. Here we demonstrate that the combination of NZI thin films into photonic multilayers like the ones found in nature enables broadband tuneable strong reflectance as well as slow light absorption enhancement and tailored photoluminescence properties in the full VIS spectrum. Moreover, it is shown that this complex optical response is tuneable, paving the way towards the development of active devices based on all polymer and near zero index materials photonic structures.