Theoretical prediction of antiferromagnetism in layered perovskite Sr2TcO4

Abstract

We theoretically investigate magnetic properties of Sr2TcO4, a 4d transition-metal layered perovskite of the K2NiF4-type with half-filled t2g states. The effect of local Coulomb repulsion between the t2g orbitals is included within the density-functional theory (DFT)+U and DFT+dynamical mean-field theory (DMFT) methods. The DFT+DMFT predicts paramagnetic Sr2TcO4 to be close to the Mott insulator-to-metal transition, similarly to the cubic compound SrTcO3. The inter-site exchange interactions computed within the DFT+DMFT framework point to a strong antiferromagnetic coupling between the neighboring Tc sites within the layer. We then evaluate the N\'eel temperature TN within a classical Monte Carlo approach including dipolar interactions, which stabilize the magnetic order in the frustrated K2NiF4 lattice structure. Our approach is applied to a set of layered and cubic perovskites. The obtained TN are in fair agreement with experiment. Within the same approach we predict TN of Sr2TcO4 to be in the 500-600K range.