DC-DFT for Open Shells: How to Deal with Spin Contamination

Abstract

Density functional theory (DFT) is widely used to predict chemical properties, but its accuracy is limited by functional approximations and their approximate self-consistent densities. Density-corrected DFT (DC-DFT) is the study of the errors due to densities and Hartree-Fock DFT (HF-DFT) uses HF densities to improve energetics. With increasing use of HF-DFT, the question of how to address strong spin contamination in the HF calculation becomes increasingly important. We compare two different open-shell HF densities across 13 different DFT functionals and two DC-DFT methods. For significant spin contamination, ROHF densities outperform UHF densities by as much as a factor of 3, depending on the energy functional, and ROHF-DFT improves over self-consistent DFT for most of the tested functionals. We refine the DC(HF)-DFT algorithm, recommending ROHF-DFT in cases of severe spin contamination.