Inter-Cation Charge Transfer Mediated Antiferromagnetism in Co1+xIr2-xS4

Abstract

The antiferromagnetism in transition metal compounds is mostly mediated by the bridging anions through a so-called superexchange mechanism. However, in materials like normal spinels AB2X4 with local moments only at the A site, such an anion-mediated superexchange needs to be modified. Here we report a new spinel compound Co1+xIr2-xS4 (x = 0.3). The physical property measurements strongly suggest an antiferromagnetic-like transition at 292 K in the Co(A) diamond sublattice. The first-principle calculations reveal that the nearest-neighbor Co(A) spins align antiferromagnetically with an ordered magnetic moment of 1.67 μB, smaller than the expected S = 3/2 for Co2+. In the antiferromagnetic state, there exists an inter-cation charge-transfer gap between the non-bonding Ir-t2g orbitals at the valence band maximum and the Co-S antibonding molecular orbitals at the conduction band minimum. The small charge transfer energy significantly enhances the virtual hopping between these two states, facilitating a robust long-range superexchange interaction between two neighboring CoS4 complexes, which accounts for the high N\'eel temperature in Co1+xIr2-xS4. This inter-cation charge transfer mediated magnetic interaction expands the traditional superexchange theory, which could be applicable in complex magnetic materials with multiple cations.

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