Band theory of insulating transition-metal monoxides: Band-structure calculations

K. Terakura; T. Oguchi; A. R. Williams; J. Kübler

doi:10.1103/PhysRevB.30.4734

Band theory of insulating transition-metal monoxides: Band-structure calculations

K. Terakura, T. Oguchi, A. R. Williams, and J. Kübler

Phys. Rev. B 30, 4734 – Published 15 October 1984

Abstract

The electronic structure of the insulating antiferromagnetic transition-metal compounds MnO, FeO, CoO, and NiO, which have been regarded as the prototypes of the concept of a Mott insulator, is discussed with use of energy-band theory based on the local-spin-density treatment of exchange and correlation. It is shown that the band structure is very sensitive to the magnetic ordering and that the ground-state magnetic ordering is special in the sense that it makes the $e_{g} (x^{2} - y^{2}, 3 z^{2} - r^{2})$ band particularly narrow, which is crucial to the insulating nature of NiO. A detailed analysis is made of this particular aspect of the ground-state magnetic ordering. As for FeO and CoO, it is suggested that the population imbalance among the $t_{2 g} (x y, y z, z x)$ orbitals induced by the intra-atomic exchange interaction may cause a gap to open at the Fermi level.