Quantifying the relative molecular orbital alignment for molecular junctions with similar chemical linkage to electrodes

TL;DR

This paper uses advanced quantum chemical calculations to accurately quantify the molecular orbital alignment in single-molecule junctions, addressing limitations of traditional DFT methods.

Contribution

It introduces the application of EOM-CCSD calculations to determine molecular orbital energies in junctions, validated against experimental data.

Findings

EOM-CCSD provides more accurate orbital alignment estimates than DFT.

Theoretical results agree well with experimental measurements.

The approach improves understanding of charge transport in molecular electronics.

Abstract

Estimating the relative alignment between the frontier molecular orbitals that dominates the charge transport through single-molecule junctions represents a challenge for theory. This requires approaches beyond the widely employed framework provided by the density functional theory, wherein the Kohn-Sham "orbitals" are treated as if they were real molecular orbitals, which is not the case. In this paper, we report results obtained by means of quantum chemical calculations, including the EOM-CCSD (equation-of-motion coupled-cluster singles and doubles), which is the state-of-the-art of quantum chemistry for medium-size molecules like those considered here. These theoretical results are validated against data on the molecular orbital energy offset relative to the electrodes' Fermi energy extracted from experiments for junctions based on 4,4'-bipyridine and 1,4-dicyanobenzene.