Insulating state and the importance of the spin-orbit coupling in Ca3CoRhO6

Abstract

We have carried out a comparative theoretical study of the electronic structure of the novel one-dimensional Ca3CoRhO6 and Ca3FeRhO6 systems. The insulating antiferromagnetic state for the Ca3FeRhO6 can be well explained by band structure calculations with the closed shell high-spin d5 (Fe3+) and low-spin t2g6 (Rh3+) configurations. We found for the Ca3CoRhO6 that the Co has a strong tendency to be d7 (Co2+) rather than d6 (Co3+), and that there is an orbital degeneracy in the local Co electronic structure. We argue that it is the spin-orbit coupling which will lift this degeneracy thereby enabling local spin density approximation + Hubbard U (LSDA+U) band structure calculations to generate the band gap. We predict that the orbital contribution to the magnetic moment in Ca3CoRhO6 is substantial, i.e. significantly larger than 1 μB per formula unit. Moreover, we propose a model for the contrasting intra-chain magnetism in both materials.