Emergent quantum criticality from spin-orbital entanglement in d8 Mott insulators: the case of a diamond lattice antiferromagnet

Abstract

Motivated by the recent activities on the Ni-based diamond lattice antiferromagnet NiRh2O4, we theoretically explore on a general ground the unique spin and orbital physics for the Ni2+ ions with a 3d8 electron configuration in the tetrahedral crystal field environment and on a diamond lattice Mott insulator. The superexchange interaction between the local moments usually favors magnetic orders. Due to the particular electron configuration of the Ni2+ ion with a partially filled upper t2g level and a fully filled lower eg level, the atomic spin-orbit coupling becomes active at the linear order and would favor a spin-orbital-entangled singlet with quenched local moments in the single-ion limit. Thus, the spin-orbital entanglement competes with the superexchange and could drive the system to a quantum critical point that separates the spin-orbital singlet and the magnetic order. We further explore the effects of magnetic field and uniaxial pressure. The non-trivial response to the magnetic field is intimately tied to the underlying spin-orbital structure of the local moments. We discuss the future experiments such as doping and pressure, and point out the correspondence between different electron configurations.