Magnetic Orders Proximal to the Kitaev Limit in Frustrated Triangular Systems: Application to Ba3IrTi2O9

Abstract

Frustrated transition metal compounds in which spin-orbit coupling (SOC) and electron correlation work together have attracted much attention recently. In the case of 5d transition metals, where SOC is large, jeff=1/2 bands near the Fermi level are thought to encompass the essential physics of the material, potentially leading to a concrete realization of exotic magnetic phases such as the Kitaev spin liquid. Here we derive a spin model on a triangular lattice based on jeff = 1/2 pseudospins that interact via antiferromagnetic Heisenberg (J) and Kitaev (K) exchanges, and crucially, an anisotropic () exchange. Our classical analysis of the spin model reveals that, in addition to small regions of 120, Z2 / dual-Z2 vortex crystal and nematic phases, the stripy and ferromagnetic phases dominate the J-K- phase diagram. We apply our model to the 5d transition metal compound, Ba3IrTi2O9, in which the Ir4+ ions form layered two-dimensional triangular lattices. We compute the band structure and nearest-neighbor hopping parameters using ab-initio calculations. By combining our ab-initio and classical analyses, we predict that Ba3IrTi2O9 has a stripy ordered magnetic ground state.