Cluster spin glass correlations and dynamics in Zn0.5Mn0.5Te

Abstract

We present a magnetometry, muon spin relaxation (μSR), and neutron scattering study of the insulating face-centered-cubic spin glass Zn0.5Mn0.5Te. The magnetometry and μSR results confirm a spin freezing transition around Tf ≈ 23 K, with the spin fluctuation rate decreasing gradually and somewhat inhomogeneously through the sample volume as the temperature decreases toward Tf. Characteristic spin correlation times well above Tf are on the order of 10-10 s, in line with expectations for a cluster spin glass. Using magnetic pair distribution function (mPDF) analysis and reverse Monte Carlo (RMC) modeling of the magnetic diffuse neutron scattering data, we show that the spin-glass ground state consists of clusters of spins exhibiting short-range-ordered type-III antiferromagnetic correlations, with a locally ordered moment of 3.1(1) μB between nearest-neighbor spins. The type-III correlations decay exponentially as a function of spin separation distance with a correlation length of approximately 5 . The diffuse magnetic scattering and corresponding mPDF show no significant changes across Tf, indicating that the dynamically fluctuating short-range spin correlations in the paramagnetic state retain the same basic type-III configuration; the only change apparent from the neutron scattering data is a gradual reduction of the correlation length and locally ordered moment with increasing temperature. Taken together, these results paint a unique and detailed picture of the local magnetic structure and dynamics in Zn0.5Mn0.5Te and show that this material is best described as a cluster spin glass. In addition, this work showcases a statistical method for extracting diffuse scattering signals from neutron powder diffraction data.

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