Pseudospin exchange interactions in d7 cobalt compounds: Possible realization of the Kitaev model

Abstract

The current efforts to find the materials hosting Kitaev model physics have been focused on Mott insulators of d5 pseudospin-1/2 ions Ir4+ and Ru3+ with t2g5(S=1/2, L=1) electronic configuration. Here we propose that the Kitaev model can be realized in materials based on d7 ions with t2g5eg2(S=3/2, L=1) configuration such as Co2+, which also host the pseudospin-1/2 magnetism. Considering possible exchange processes, we have derived the d7 pseudospin-1/2 interactions in 90 bonding geometry. The obtained Hamiltonian comprises the bond-directional Kitaev K and isotropic Heisenberg J interactions as in the case of d5 ions. However, we find that the presence of additional, spin-active eg electrons radically changes the balance between Kitaev and Heisenberg couplings. Most remarkably, we show that the exchange processes involving eg spins are highly sensitive to whether the system is in Mott (U<) or charge-transfer (U>) insulating regime. In the latter case, to which many cobalt compounds do actually belong, the antiferromagnetic Heisenberg coupling J is strongly suppressed and spin-liquid phase can be stabilized. The results suggest cobalt-based materials as promising candidates for the realization of the Kitaev model.