Non-magnetic ground state of PuO2

Abstract

The correlated band theory implemented as a combination of the local density approximation with the exact diagonalization of the Anderson impurity model is applied to PuO2. We obtain an insulating electronic structure consistent with the experimental photoemission spectra. The calculations yield the band gap of 1.8 eV and a non-magnetic singlet ground state that is characterized by a non-integer filling of the plutonium f shell (nf≈ 4.5). Due to sizeable hybridization of the f shell with the p states of oxygen, the ground state is more complex than the four-electron Russell--Saunders 5 I4 manifold split by the crystal field. The inclusion of hybridization improves the agreement between the theory and experiment for the magnetic susceptibility.