The correlation energy as an explicit functional of the one-particle density matrix from a determinantal reference state
Abstract
Using an approach based on many body perturbation theory, the correlation energy is expressed as an explicit functional of 1, v, and vs, where 1 is the one-particle density matrix from the noninteracting, or reference, determinantal-state; v is the external potential from the interacting, or target, state; vs is the (kernel of the) external potential from the noninteracting determinantal-state. In other words we have [1,v,vs]. Anther possibility is the following explicit functional: [1,vco,vs], where vco is the (kernel of the) correlation potential from the noninteracting Hamiltonian. The proposed method can, in principle, be used to compute in a very accurate and efficient manner, since, like the Kohn--Sham approach, there are no virtual orbitals to consider. However, in contrast to the Kohn--Sham approach, is a known, explicit functional that can be approximated in a systematic manner. For simplicity, we only consider noninteracting closed-shell states and target states that are nondegenerate, singlet ground-states; so, in that case, 1 denotes the spin-less one-particle density matrix from the determinantal reference state.
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