Melanin thin-films: a perspective on optical and electrical properties

Melanins are an essential natural pigment found throughout nature. Due to their inherent biocompatibility, optical and electronic properties, the melanins are attracting attention as model materials for sustainable organic optoelectronic and bioelectronic applications. Standard melanin is notoriously insoluble, which complicates processability considerably. Hence, the creation of synthetic derivatives that have similar optical-electronic properties but with increased solubility are avenues of active investigation. In this work, we investigate soluble non-functionalised (NF) and sulfonated (S) melanin derivatives. So far, these new synthetic derivatives' optical and electrical properties have not been explored in full, which would allow their effective application in optoelectronic devices. Our optical results suggest that these materials have high refractive indices and also high dispersion and chromatic aberration. In addition, no significant differences in NF-melanin's charge transport deposited from pure water or aqueous ammonia solution were observed, and S-melanin's functional groups did not affect the hydration-dependence conductivity, only its sensitivity to environmental humidity. The similarities and differences in spectra and values comparing NF and S-melanin are discussed based on their structural differences.

Automated summary

Melanins are a crucial natural pigment in nature and are being explored for their potential in sustainable organic optoelectronic and bioelectronic applications. This study investigates the optical and electrical properties of soluble non-functionalised (NF) and sulfonated (S) melanin derivatives, discussing their similarities and differences in spectra and values based on structural variances. The results suggest high refractive indices, dispersion, and chromatic aberration in these materials, providing insights for their application in optoelectronic devices.