Magnetism of (LaCoO3)n+(LaTiO3)n superlattices with n=1,2

Abstract

LaCoO3 provides a poignant example of a transition metal oxide where the cobalt cations display multiple spin states and spin transitions and which continues to garner substantial attention. In this work, we describe first principles studies, based on DFT+U theory, of superlattices containing LaCoO3, specifically (LaCoO3)n+(LaTiO3)n for n=1,2. The superlattices show strong electron transfer from Ti to Co resulting in Co2+, significant structural distortions and a robust orbital polarization of Co2+. We predict high-spin Co2+ and a checkerboard or G-type antiferromagnetic (AFM) ground state. We provide a detailed analysis of the magnetic interactions and phases in the superlattices. We predict that ferromagnetic order on the Co2+ can be stabilized by hole doping (e.g., replacing La by Sr) which is rather unusual for Co2+ cations.