Spin-orbit coupling in a half-filled t2g shell: the case of 5d3 K2ReCl6
Abstract
The half-filled t2g shell of the t2g3 configuration usually, in LS coupling, hosts a S = 3/2 ground state with quenched orbital moment. This state is not Jahn-Teller active. Sufficiently large spin-orbit coupling ζ has been predicted to change this picture by mixing in orbital moment, giving rise to a sizable Jahn-Teller distortion. In 5d3 K2ReCl6 we study the electronic excitations using resonant inelastic x-ray scattering (RIXS) and optical spectroscopy. We observe on-site intra-t2g excitations below 2 eV and corresponding overtones with two intra-t2g excitations on adjacent sites, the Mott gap at 2.7 eV, t2g-to-eg excitations above 3 eV, and charge-transfer excitations at still higher energy. The intra-t2g excitation energies are a sensitive measure of ζ and Hund's coupling JH. The sizable value of ζ ≈ 0.29 eV places K2ReCl6 into the intermediate coupling regime, but ζ/JH ≈ 0.6 is not sufficiently large to drive a pronounced Jahn-Teller effect. We discuss the ground state wavefunction in a Kanamori picture and find that the S = 3/2 multiplet still carries about 97 % of the weight. However, the finite admixture of orbital moment allows for subtle effects. We discuss small temperature-induced changes of the optical data and find evidence for a lowering of the ground state by about 3 meV below the structural phase transitions.
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