Determination of the Magnetic Structure of Spin Glass Compound $\text{Zn}_{0.5}\text{Mn}_{0.5}\text{Te}$ Using Real-Space Methods

We present a combined magnetometry, muon spin relaxation ($\mu$SR), and neutron scattering study of the insulating spin glass Zn$_{0.5}$Mn$_{0.5}$Te, for which magnetic Mn$^{2+}$ and nonmagnetic Zn$^{2+}$ ions are randomly distributed on a face-centered cubic lattice. Using magnetic pair distribution function (mPDF) analysis and reverse Monte Carlo (RMC) modeling of the diffuse magnetic scattering, we show that the spin-glass ground state exhibits short-range type-III antiferromagnetic order with a locally ordered moment of 3.4 $\mu_{\mathrm{B}}$ between nearest-neighbor spins, which decays as a function of spin separation distance with a correlation length of approximately 5 {\AA}. The diffuse magnetic scattering and corresponding mPDF show no significant changes across the spin-glass freezing temperature $T_f = 22$ K, indicating that the dynamically fluctuating short-range spin correlations in the paramagnetic state retain the same basic type-III configuration that characterizes the spin-glass state; the only change apparent from the neutron scattering data is a gradual reduction of the correlation length and locally ordered moment with increasing temperature. The $\mu$SR results demonstrate that fluctuation rate of the short-range spin correlations decreases gradually and somewhat inhomogeneously through the sample volume as the temperature decreases toward $T_f$. Taken together, these results provide a unique and detailed picture of the local magnetic structure and dynamics in a concentrated spin glass. In addition, this work showcases a new statistical method for extracting diffuse scattering signals from neutron powder diffraction data, which we developed to facilitate the mPDF and RMC analysis of the neutron data. This method has the potential to be broadly useful for neutron powder diffraction experiments on a variety of materials with short-range atomic or magnetic order.