Fabrication of doped ferrites and exploration of their structure and magnetic behavior

Manganese-doped MnxFe3-xO4 (x = 0.0, 0.2, 0.6, 0.8) spinel ferrites were produced via co-precipitation using the ethanolamine. XRD results confirmed the formation of the spinel phase. The well-crystallized particles of the ferrite spinel phase had linear sizes in the range of 5-9 nm. It was found that the lattice parameter increases gradually as the Mn concentration is increased. XPS data supported the presence of Mn3+ and Mn4+ in the nanosized crystallites. A large specific surface area of 124-143 m(2) g(-1) was calculated using HRTEM and BET. The spontaneous magnetization increases monotonically from similar to 51 emu g(-1) for x = 0.0 up to similar to 106 emu g(-1) for x = 0.8. By contrast, the remanent magnetization changed non-monotonically from similar to 3 emu g(-1) for x = 0.0 up to similar to 11 emu g(-1) for x = 0.8, with a local maximum of similar to 7 emu g(-1) for x = 0.2 and a local minimum of similar to 3 emu g(-1) for x = 0.6. The coercivity also changed non-monotonically from similar to 4 Oe for x = 0.0 up to similar to 9 Oe for x = 0.8, with a minimum of similar to 1 Oe for x = 0.2. The ordered magnetic moments for each sub-lattice were computed. The large values of the specific surface area indicate that the samples are good candidates for chemical and biological applications. The FT-IR and Raman spectra obtained supported the Rietveld refinement of XRD without forming any impurity phases. With an increase in the Mn concentration, magnetic investigations indicated an enhancement in the magnetic parameters of the obtained nanostructured samples.

Automated summary

Manganese-doped MnxFe3-xO4 spinel ferrites with different Mn concentrations were successfully fabricated using co-precipitation. The XRD results confirmed the formation of spinel phase with well-crystallized particles and the lattice parameter increased with increasing Mn concentration. XPS data supported the presence of Mn3+ and Mn4+ in the nanosized crystallites. The samples exhibited a large specific surface area and showed potential for chemical and biological applications. Magnetic investigations revealed an enhancement in the magnetic parameters of the nanostructured samples with an increase in Mn concentration.