posted on 2023-05-23, 20:15authored byPierpaolo Morgante, Jochen Autschbach
Density-corrected (DC) density functional theory (DFT)
has been
proposed to overcome difficulties related to the self-interaction
error. The procedure uses the Hartree–Fock electron density
(matrix) non-self-consistently in conjunction with an approximate
functional. DC-DFT has so far mainly been tested for total energy
differences, whereas other types of molecular properties have not
been evaluated systematically. This work focuses on the performance
of DC-DFT for molecular properties, namely, dipole moments, static
polarizabilities, and electric field gradients (EFGs) at atomic nuclei.
Accurate reference data were generated from coupled-cluster theory
to assess the performance of DC and self-consistent DFT calculations
for twelve molecules, including diatomics with transition metals.
DC-DFT does no harm in dipole moment calculations, but it negatively
impacts the polarizability in at least one case. DC-DFT performs well
for EFGs, even for the difficult case of CuCl.