Single determinant approximation for ground and excited states with accuracy comparable to that of the configuration interaction

Abstract

It was realized from the early days of Chemical Physics (Rev. Mod. Phys. 35, 496 (1963)) that the energy EHF of the Slater determinant (SlDet) | HF, obtained by the single particle Hartree-Fock (HF) equation, does not coincide with the minimum energy of the functional |H| where | is a SlDet and H is the many particle Hamiltonian. However, in most textbooks, there is no mention of this fact. In this paper, starting from a Slater determinant | with its spin orbitals calculated by the standard HF equation or other approximation, we search for the maximum of the functional | |H| |, where | is a SlDet and H is the exact Hamiltonian of an atom or a molecule. The element | 1|H| | with | 1 the maximizing | gives a value larger than |H|. The next step is to calculate the corresponding maximum overlap 2|H| 1| and subsequently | n+1|H| n| until | m+1|H| m - m-1|H| m|≤, where determines the required numerical accuracy. We show that the sequence an=| n+1|H|n| is ascending and converges. We applied this procedure for determining the eigenstate energies of several configurations of H3, the Lithium atom, LiH and Be. After comparing our values with those of the configuration interaction we found that our deviations are in the range 10-5~to 10-8 and the ground state energy is significantly below that of the standard HF calculations.