Strain and correlation induced half-metallic ferromagnetism in orthorhombic BaFeO3

Abstract

Using first-principles calculations, the electronic and magnetic properties of orthorhombic BaFeO3 (BFO) are investigated with local spin density approximation (LSDA). The calculations reveal that at the optimized lattice volume BFO has a lower energy in ferromagnetic state as compared with antiferromagnetic state. At the equilibrium volume, BFO shows metallic behavior, however, under a large tensile strain (25\%), BFO shows half-metallic behavior consistent with the integer magnetic moment of 4.0μB/fu mainly caused by the t2g and eg electrons of Fe. Including a Hubbard-like contribution U (LSDA+U) on Fe d states induced half-metallic bahvior without external strain, which indicates that U can be used to tune the electronic structure of BFO. The magnetic moments remained robust against 10\% compressive and tensile strain. At large compressive (tensile) strain, the half-metallicity of BFO is mainly destroyed by the Fe-d (O-p) electrons in agreement with the non-integer value of the magnetic moments of BFO.