Ab initio electronic structure calculations of solid, solution-processed metallotetrabenzoporphyrins

TL;DR

This study uses ab initio calculations to analyze how different metal core substitutions in solid metallotetrabenzoporphyrins affect their electronic structures, relevant for organic electronics.

Contribution

It provides detailed electronic structure data for MTBPs with various metal cores, highlighting how core substitution influences band structure and defect states.

Findings

Cu and Ni substitutions create nearly flat bands near band edges.

Core substitution alters the density of states and bandgap characteristics.

Structural similarities do not imply identical electronic properties.

Abstract

An ab initio study of the electronic structures of solid metallotetrabenzoporphyrins (MTBPs) utilized in organic transistors and photovoltaics is presented. Bandstructures, densities of states, and orbitals are calculated for H2, Cu, Ni, and Zn core substitutions of the unit cell of solid TBP, as deposited via soluble precursors that are thermally annealed to produce polycrystalline, semiconducting thin-films. While the unit cells of the studied MTBPs are nearly isomorphous, substitution of the core atoms alters the structure of the bands around the energy bandgap and the composition of the densities of states. Cu and Ni core substitutions introduce nearly-dispersionless energy bands near the valence and conduction band edges, respectively, that form acceptor or deep generation/recombination states.