Litcius/Paper detail

Single Excitation Energies Obtained from the Ensemble “HOMO–LUMO Gap”: Exact Results and Approximations

Tim Gould, Zahed Hashimi, Leeor Kronik, Stephen G. Dale

2022The Journal of Physical Chemistry Letters47 citationsDOI

Abstract

In calculations based on density functional theory, the "HOMO-LUMO gap" (difference between the highest occupied and lowest unoccupied molecular orbital energies) is often used as a low-cost, ad hoc approximation for the lowest excitation energy. Here we show that a simple correction based on rigorous ensemble density functional theory makes the HOMO-LUMO gap exact in principle and significantly more accurate in practice. The introduced perturbative ensemble density functional theory approach predicts different and useful values for singlet-singlet and singlet-triplet excitations, using semilocal and hybrid approximations. Excitation energies are similar in quality to time-dependent density functional theory, especially at high fractions of exact exchange. The approach therefore offers an easy-to-implement and low-cost route to robust prediction of molecular excitation energies.

Topics & Concepts

Density functional theoryHOMO/LUMOExcitationSinglet stateHybrid functionalOrbital-free density functional theoryPhysicsTime-dependent density functional theoryBand gapQuantum mechanicsAtomic physicsExcited stateMoleculeAdvanced Chemical Physics StudiesMachine Learning in Materials ScienceCatalysis and Oxidation Reactions
Single Excitation Energies Obtained from the Ensemble “HOMO–LUMO Gap”: Exact Results and Approximations | Litcius