Magnetic Properties of Mechano-Thermally Processed Nanocrystalline MgFe2O4 Spinel Materials

This work highlights the results obtained from different characterizations for the Mg-based spinel ferrite, MgFe2O4 nanomaterials prepared by ball milling followed by annealing at different temperatures, 800 degrees C, 900 degrees C, 1000 degrees C, and 1100 degrees C each for 2 h. From XRD analysis, the structural data such as lattice parameter, average crystalline size, micro-strain, and dislocation density of different MgFe2O4 samples are obtained. While the produced as-milled powder revealed the majority of the peaks are cubic MgFe2O4 phase materials, the annealed samples yielded phase pure nanocrystalline cubic spinel MgFe2O4 materials. The photoluminescence (PL) intensity of emission peak seen at similar to 417 nm (lambda(excitation) = 375 nm) for different nanocrystalline MgFe2O4 materials varies regardless of the annealing temperatures. The FT-IR results imply the intrinsic stretching vibrations of the Fe-O at the tetrahedral site for these spinel materials. A gradual increase of the saturation magnetization was observed for the present MgFe2O4 materials upon increasing the annealing temperature. These nanocrystalline MgFe2O4 materials may have potential applications in magnetic fluid (hyperthermia) and near-infrared (NIR) pigment applications.

Automated summary

This study focused on the characterization of MgFe2O4 nanomaterials prepared by ball milling and annealing at different temperatures. The results showed variations in structural properties and magnetization behavior of the materials, which could impact their potential applications in magnetic fluid and NIR pigment applications.