XRD, microstructural and EPR susceptibility characterization of combustion synthesized nanoscale Mg1−xNixO solid solutions

The lattice parameter a(x) of the stoichiometric Mg_1−xNi_xO (0?x?1) solid solutions prepared by urea-based combustion synthesis with fuel to oxidizer ratio (ψ=1) was determined by X-ray diffraction. It was found that the dependence of the lattice parameter a(x) on the composition deviated more from the linear Vegard's model (VM) when compared to Kuzmin-Mironova (KM) model. a(x) in the Mg_1−xNi_xO system differs nontrivially from the predictions of both VM and KM models. For x=0.4 (Mg_0.6Ni_0.4O), the maximum deviation was about 2 and 1.7 pm, respectively. The increase in the intensity of (1 1 1) peak in XRD with increase of nickel concentration confirms that the substitution induces changes at the unit cell level. Nelson-Riley function (NRF) and Williamson-Hall plots are used to calculate micro strain in the solid solution. This analysis indicates that the micro strain is maximum for the compositions 60-40 (Mg_0.6Ni_0.4O), 50-50 (Mg_0.5Ni_0.5O) and 40-60 (Mg_0.4Ni_0.6O). The crystallite size was estimated using Williamson-Hall plot. We conclude that almost similar sized crystallite is formed in all the compositions studied. Porosity determined using XRD increases with a raise in the nickel concentration. The SEM morphology provides corroborative evidence. EPR susceptibilities of solid solution Mg_1−xNi_xO are determined at room temperature. Variable temperature of EPR allowed to check the Curie-Weiss law for solid solution. The linearity of C_M(x) and Θ(x) with concentration of nickel has ruled out chemical clustering in the samples.