Breakdown of Jeff = 0 and Jeff = 3/2 states and existence of large magnetic anisotropy energy in vacancy ordered 5d antifluorites: K2ReCl6, K2OsCl6, and K2IrCl6

Abstract

Vacancy-ordered antifluorite materials (A2BX6) are garnering renewed attention as novel magnetic states driven by spin-orbit coupling (SOC) can be realized in them. In this work, by pursuing density functional theory calculations and model studies, we analyze the ground state electronic and magnetic structure of face-centered cubic (fcc) antifluorites K2ReCl6 (KReC, 5d3), K2OsCl6 (KOsC, 5d4), and K2IrCl6 (KIrC, 5d5). We find that KReC stabilizes in the high-spin S = 3/2 state instead of the expected pseudo-spin Jeff = 3/2 state. The former occurs due to large exchange-splitting as compared to the SOC strength. On the contrary, the KOsC stabilizes in broken Jeff = 0 (S = 1) simple Mott insulating state while KIrC stabilizes in Jeff = 1/2 spin-orbit-assisted Mott insulating state. The presence of an isolated metal-chloride octahedron makes these antifluorites weakly coupled magnetic systems with the nearest and next-nearest-neighbor spin-exchange parameters (J1 and J2) are of the order of 1 meV. For KReC and KOsC, the J1 and J2 are estimated to be antiferromagnetic and ferromagnetic, which leads to a Type-I antiferromagnetic ground state, whereas for KIrC, both J1 and J2 are antiferromagnetic, hence, it stabilizes with a Type-III antiferromagnetic state. Interestingly, in their equilibrium structure, these antifluorites possess large magnetic anisotropy energy (0.6-4 meV/transition metal), which is at least one-to-two orders higher than traditional MAE materials like transition metals and multilayers formed out of them. Moreover, with epitaxial tensile/compressive strain, the MAE enhances by one order, becoming giant for KOsC (20-40 meV/Os).