Two-orbital eg model with bond-dependent spin-orbit coupling: A playground for emergent band topology, Kitaev magnetism, and magnetoelectricity

Abstract

Inspired by the electronic structure of compounds like nickel dihalides NiX2 (X=Cl, Br, I), we propose a low-energy two-orbital eg model featuring bond-dependent spin-orbit terms, driven by atomic spin-orbit coupling on the ligand X. We demonstrate that this model hosts a rich array of phenomena. In the non-interacting band limit, spin-orbit-derived spin-dependent and spin-flip hopping terms produce topological bands with spin-Chern numbers Cs= 2, 4, and higher order topological states with fractional corner charges, respectively. In the half-filled Mott insulator limit, we recover a spin-1 Hamiltonian with bond-dependent Kitaev exchange interactions. We explore the magnetoelectric effect in this two-orbital model using symmetry-based perspective and microscopic calculations, going beyond the generalized Katsura-Nagaosa-Balatsky theory for the single-orbital case. Our work may be relevant to study of doping, strain, or pressure on NiX2 and related materials.