Magnetic susceptibilities in a family of S=1/2 Kagome antiferromagnet

Abstract

Hexagonal antiferromagnets Cs2Cu3MF12 (M = Zr, Hf and Sn) have uniform Kagome lattices of Cu2+ with S = 1/2, whereas Rb2Cu3SnF12 has a 2a by 2a enlarged cell as compared with the uniform Kagome lattice. The crystal data of Cs2Cu3SnF12 synthesized first in the present work are reported. We performed magnetic susceptibility measurements on this family of Kagome antiferromagnet using single crystals. In the Cs2Cu3MF12 systems, structural phase transitions were observed at Tt = 225 K, 172 K and 185 K for M = Zr, Hf and Sn, respectively. The magnetic susceptibilities observed for T > Tt are almost perfectly described using theoretical results obtained by exact diagonalization for the 24-site Kagome cluster with J/kB = 244 K, 266 K and 240 K, respectively. Magnetic ordering accompanied by the weak ferromagnetic moment occurs at TN = 23.5 K, 24.5 K and 20.0 K, respectively. The origins of the weak ferromagnetic moment should be ascribed to the lattice distortion that breaks the hexagonal symmetry of the exchange network for T < Tt and the Dzyaloshinsky-Moriya interaction. Rb2Cu3SnF12 is magnetically described as a modified Kagome antiferromagnet with four types of neighboring exchange interaction. Neither structural nor magnetic phase transition was observed in Rb2Cu3SnF12. Its magnetic ground state was found to be a spin singlet with a triplet gap. Using exact diagonalization for a 12-site Kagome cluster, we analyzed the magnetic susceptibility and evaluated individual exchange interactions. The causes leading to the different ground states in Cs2Cu3SnF12 and Rb2Cu3SnF12 are discussed.