Locating the bandgap edges of eumelanin thin films for applications in organic green electronic

BACKGROUND Bio-sourced (natural) organic materials are often chemically and structurally disordered, such that their structure-property relationships must be explored using model systems. Eumelanin is an interesting candidate among natural organic materials. RESULTS In this work, the locations of the highest occupied molecular orbital (HOMO) and the lowest unoccupied molecular orbital (LUMO) energy levels of 5,6-dihydroxyindole (DHI) and 5,6-dihydroxyindole-2-carboxylic acid (DHICA) building blocks (monomers) of the black-brown biopigment eumelanin, in film form, are studied. The films are fabricated by the spin-coating technique (i.e., here indicated as DHI- and DHICA-films), which is sometimes followed by ammonia-induced solid-state polymerization (i.e., indicated as AISSP-DHI and AISSP-DHICA films), as well as by thermal evaporation (i.e., evaporated DHI and DHICA films). From Ultraviolet photoemission spectroscopy (UPS), we deduced the ionization energies (EI) for all DHI- and DHICA-based films to be in the range of 5.34-5.56 eV and 5.35-5.80 eV, respectively. The electron affinities (chi E) are measurable using inverse photoemission spectroscopy (IPES) for DHI films (3.80 eV) and both evaporated DHI (4.0 eV) and DHICA (3.9 eV) films. On the other hand, the chi E values of DHICA, AISSP-DHI, and AISSP-DHICA films are estimated with about 0.5 eV of uncertainty. UV-visible spectroscopy reveals the preferred chromophoric bands for DHICA, AISSP-DHICA, and DHI are in the range of 300-330 nm, while AISSP-DHI exhibits a broadened UV-visible absorbance. CONCLUSION Our study paves the way for the design of suitable metal-eumelanin interfaces for electronic applications. (c) 2021 Society of Chemical Industry (SCI).