Importance of anisotropic Coulomb interactions in the electronic and magnetic properties of Mn3O4

Abstract

We report the importance of anisotropic Coulomb interactions in DFT+U calculations of the electronic and magnetic properties of Mn3O4. The effects of anisotropic interactions in Mn2+ and Mn3+ are separately examined by defining two different sets of Hubbard parameters: U2+ and J2+ for Mn2+ and U3+ and J3+ for Mn3+. The anisotropic interactions in Mn3+ have a significant impact on the physical properties of Mn3O4 including local magnetic moments, canted angle, spontaneous magnetic moment, and superexchange coupling, but those in Mn2+ do not make any noticeable difference. Weak ferromagnetic interchain superexchange, observed in experiments, is predicted only if a sizable anisotropic interaction is considered in Mn3+. By analyzing the eigenoccupations of the on-site Mn density matrix, we found that the spin channel involving Mn3+ dx2-y2 orbitals, which governs the 90 correlation superexchange, is directly controlled by the anisotropic interactions. These findings demostrate that the exchange correction J for the intraorbital Coulomb potential is of critical importance for first-principles description of reduced Mn oxides containing Mn3+ or Mn4+.