Charge-state dependent spin-orbit coupling and quantum phase transitions in Ir-Ru oxides
Abstract
The competition between kinematic, relativistic and Coulombic interactions in iridium-based oxides has spurred intense experimental and theoretical investigations regarding the electronic structure and magnetism. We argue here that the Iridium-Ruthenium triple perovskites, Ba3MRuIrO9 (M = Li, Mg and In), are of particular interest in this regard. We show here, using ab-initio theory, that the nominal charge states of Ir can be tuned from +6 to +4 by choosing non-magnetic 'M' ions as Li (+1), Mg(+2) and In (+3). This variation modulates the influence of the spin-orbit coupling (SOC) which is found here to be negligible in Ba3LiRuIrO9, moderate in Ba3MgRuIrO9 and determining in Ba3InRuIrO9. Our analysis classifies Ba3LiRuIrO9 as a band-insulator, Ba3MgRuIrO9 as a SOC and correlation driven insulator and Ba3InRuIrO9 as J eff = 1/2 Mott-Hubbard insulator. As reported here, correlated electronic structure theory results in sizeable magnetic moments of both Ru and Ir atoms in these systems and atomistic spin-dynamics simulations capture the experimental N\'eel temperature for Ba3LiRuIrO9 and Ba3MgRuIrO9 and provide evidence for a phase transition for Ba3InRuIrO9 when T 0 K, to a multi-valley magnetic state with strong magnetic frustration. The theory identifies the presence of Kitaev interaction among the iridium atoms in Ba3InRuIrO9. The realization of such strong anisotropic interactions helps to stabilize a particularly complex energy landscape of Ba3InRuIrO9, that opens up for exotic magnetic quantum phases.
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