CuSiO3 : a quasi - one - dimensional S=1/2 antiferromagnetic chain system

Abstract

CuSiO3, isotypic to the spin - Peierls compound CuGeO3, was discovered recently as a metastable decomposition product of the silicate mineral dioptase, Cu6Si6O18·6H2O. We investigated the physical properties of CuSiO3 using susceptibility, magnetization and specific heat measurements on powder samples. The magnetic susceptibility (T) is reproduced very well above T = 8 K by theoretical calculations for an S=1/2 antiferromagnetic Heisenberg linear chain without frustration (α = 0) and a nearest - neighbor exchange coupling constant of J/kB = 21 K, much weaker than in CuGeO3. Below 8 K the susceptibility exhibits a substantial drop. This feature is identified as a second - order phase transition at T0 = 7.9 K by specific heat measurements. The influence of magnetic fields on T0 is weak, and ac - magnetization measurements give strong evidence for a spin - flop - phase at μ0HSF ~ 3 T. The origin of the magnetic phase transition at T0 = 7.9 K is discussed in the context of long - range antiferromagnetic order (AF) versus spin - Peierls(SP)order. Susceptibility and specific heat results support the AF ordered ground state. Additional temperature dependent 63,65Cu nuclear quadrupole resonance experiments have been carried out to probe the Cu2+ electronic state and the spin dynamics in CuSiO3.

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