Orbital Configurations and Magnetic Properties of Double-Layered Antiferromagnet Cs3Cu2Cl4Br3
Abstract
We report the single-crystal X-ray analysis and magnetic properties of a new double-layered perovskite antiferromagnet, Cs3Cu2Cl4Br3. This structure is composed of Cu2Cl4Br3 double layers with elongated CuCl4Br2 octahedra and is closely related to the Sr3Ti2O7 structure. An as-grown crystal has a singlet ground state with a large excitation gap of /k B 2000 K, due to the strong antiferromagnetic interaction between the two layers. Cs3Cu2Cl4Br3 undergoes a structural phase transition at T s330 K accompanied by changes in the orbital configurations of Cu2+ ions. Once a Cs3Cu2Cl4Br3 crystal is heated above T s, its magnetic susceptibility obeys the Curie-Weiss law with decreasing temperature even below T s and does not exhibit anomalies at T s. This implies that in the heated crystal, the orbital state of the high-temperature phase remains unchanged below T s, and thus, this orbital state is the metastable state. The structural phase transition at T s is characterized as an order-disorder transition of Cu2+ orbitals.
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