Configuration-interaction calculations with density-functional theory molecular orbitals for modeling valence- and core-excited states in molecules

Abstract: We investigate configuration-interaction (CI) calculations on a basis of molecular orbitals generated by preliminary density-functional theory (DFT) calculations. We use this CI/DFT framework to improve the modeling of core-excited states by exploiting the flexibility and account for electron correlation of DFT orbitals compared to the canonical Hartree-Fock analogs. We assess the performance of our approach on the valence- and core-excited electronic states of three molecules with increasing levels of electron-correlation complexity: the singly bonded CH4, doubly bonded CO2, and triply bonded N2. For molecules with strong electron correlation effects, such as CO2 and N2, the inclusion of double excitations is important to model the core-hole excited states with reasonable accuracy. CI/DFT outperforms standard single-reference CI on Hartree-Fock molecular orbitals and competes with multi-reference CI calculations with multi-configuration self-consistent field orbitals in the modeling of molecules with strong electron-correlation effects, but weak multi-reference nature of their wave function such as CO2. In contrast, the choice of the molecular-orbital basis is irrelevant when modeling systems with negligible electron-correlation effects like CH4 or important multi-reference nature of their wave function like N2.