Formation of isomorphic Ir3+ and Ir4+ octamers and spin dimerization in the spinel CuIr2S4

Abstract

Inorganic compounds with the AB₂X₄ spinel structure have been studied for many years, because of their unusual physical properties. The spinel crystallographic structure, first solved by Bragg in 1915¹, has cations occupying both tetrahedral (A) and octahedral (B) sites. Interesting physics arises when the B-site cations become mixed in valence. Magnetite (Fe₃O₄) is a classic and still unresolved example, where the tendency to form ordered arrays of Fe²⁺ and Fe³⁺ ions competes with the topological frustration of the B-site network². The CuIr₂S₄ thiospinel is another example, well known for the presence of a metal–insulator transition at 230 K with an abrupt decrease of the electrical conductivity on cooling accompanied by the loss of localized magnetic moments^3,4,5,6,7. Here, we report the determination of the crystallographic structure of CuIr₂S₄ below the metal–insulator transition. Our results indicate that CuIr₂S₄ undergoes a simultaneous charge-ordering and spin-dimerization transition—a rare phenomenon in three-dimensional compounds. Remarkably, the charge-ordering pattern consists of isomorphic octamers of Ir₈³⁺S₂₄ and Ir₈⁴⁺S₂₄ (as isovalent bi-capped hexagonal rings). This extraordinary arrangement leads to an elegant description of the spinel structure, but represents an increase in complexity with respect to all the known charge-ordered structures, which are typically based on stripes, slabs or chequerboard patterns.