摘要
Motivated by recent experimental observations of metallic conduction in the quasi-two-dimensional SrFeO_2, we study the epitaxial strain effect on the formation and electronic structures of oxygen vacancy(Vo) by first-principles calculations.The bulk SrFeO_2 is found to have the G-type antiferromagnetic ordering(G-AFM) at zero strain, which agrees with the experiment. Under compressive strain the bulk SrFeO_2 keeps the G-AFM and has the trend of Mott insulator-metal transition.Different from most of the previous similar work about the strain effect on Vo, both the tensile strain and the compressive strain enhance the Vo formation. It is found that the competitions between the band energies and the electrostatic interactions are the dominant mechanisms in determining the Vo formation. We confirm that the Vo in SrFeO_2 would induce the n-type conductivity where the donor levels are occupied by the delocalized d_(x^2-y^2) electrons. It is suggested that the vanishing of n-type conductivity observed by the Hall measurement on the strained films are caused by the shift of donor levels into the conduction band. These results would provide insightful information for the realization of metallic conduction in SrFeO_2.
Motivated by recent experimental observations of metallic conduction in the quasi-two-dimensional SrFeO_2, we study the epitaxial strain effect on the formation and electronic structures of oxygen vacancy(Vo) by first-principles calculations.The bulk SrFeO_2 is found to have the G-type antiferromagnetic ordering(G-AFM) at zero strain, which agrees with the experiment. Under compressive strain the bulk SrFeO_2 keeps the G-AFM and has the trend of Mott insulator-metal transition.Different from most of the previous similar work about the strain effect on Vo, both the tensile strain and the compressive strain enhance the Vo formation. It is found that the competitions between the band energies and the electrostatic interactions are the dominant mechanisms in determining the Vo formation. We confirm that the Vo in SrFeO_2 would induce the n-type conductivity where the donor levels are occupied by the delocalized d_(x^2-y^2) electrons. It is suggested that the vanishing of n-type conductivity observed by the Hall measurement on the strained films are caused by the shift of donor levels into the conduction band. These results would provide insightful information for the realization of metallic conduction in SrFeO_2.
基金
Project supported by the Creative Plan Project of Nanjing Forest Police College,China(Grant Nos.201512213045xy and 201512213007x)
