Effect of calcium solubility on structural, microstructural and magnetic properties of M-type barium hexaferrite

We report the synthesis of x = 0.00-1.00 at step size of 0.10 for Ba1-xCaxFe12O19 samples using sol-gel auto combustion method. The powder X-ray diffraction (XRD) data of samples calcined at different temperatures indicates a) single phase formation up to x = 0.20 in samples calcined at 900 degrees C; b) an increase in calcium solubility to 50 at. % (x = 0.50) at 1200 degrees C; c) a decrease in lattice parameters 'c' (from 23.2002 angstrom (x = 0.00) to 23.0928 angstrom (x = 0.50)) as well as cell volume (from 696.75 angstrom 3 (x = 0.00) to 692.95 angstrom 3 (x = 0.50)) with increasing 'x' and d) the presence of segregated (alpha-Fe2O3) phase for x >= 0.20 at 900 degrees C and for x > 0.50 at 1200 degrees C. As the maximum calcium solubility in BaM phase has been noticed at 1200 degrees C, most of the other characterizations have been performed on these samples only. FESEM micrographs show an increase in particle size with 'x'. Magnetic measurements reveal that the highest value of saturation magnetization (Ms) is approximate to 71.82 emu/g (calcined at 1200 degrees C) in x = 0.50 sample. The coercivity (Hc) decreases from 3765Oe to 1729Oe with increase in 'x'. Among the samples calcined at different temperatures, the coercivity (Hc) decreases from 4726Oe to 2040Oe with an increase in calcination temperature for x = 0.20 samples. The samples because of their excellent magnetic properties could be vital for magnetic recording and for applications as permanent magnets.

Automated summary

In this study, Ba1-xCaxFe12O19 samples were synthesized using sol-gel auto-combustion method, with the maximum calcium solubility observed at 1200 degrees C. The XRD data showed a decrease in lattice parameters and cell volume with increasing 'x', while FESEM images revealed an increase in particle size. Magnetic measurements indicated that the highest saturation magnetization was found in the x = 0.50 sample, with a decrease in coercivity as 'x' increased.