Effect of aluminum substitution on microstructure and magnetic properties of electrospun BaFe12O19 nanofibers

BaFe 12− x Al x O 19 nanofibers ( x = 0–2.0) with average diameter 110 nm have been prepared via the electrospinning and subsequent heat treatment at 1100 °C for 2 h. Individual BaFe 12 O 19 nanofibers were composed of numerous nanocrystallites stacking alternatively along the long axis of fiber and the single crystallites on each nanofibers had random orientations. With increasing Al 3+ ions substitution contents from 0 to 2.0, the diameter and morphology of nanofibers were almost no change. However, the lattice parameters decreased due to Fe 3+ ions substituted by smaller Al 3+ ions and the average grain size calculated by the Scherrer’s equation reduced from 47 to 42 nm. The crystallites possessed a hexagonal plate-like shape at x = 0 while they became rod-like with various Al 3+ ions substitution. The X-ray diffraction patterns show that single-phase barium hexaferrite was formed when Al 3+ ions substitution contents were less than and equal to 1.0, while other impurity phases were detected when they were more than 1.0. The chemical analysis shows that the element Al was all incorporated into the lattice of BaFe 12 O 19 and evenly distributed throughout the BaFe 12− x Al x O 19 nanofibers. The magnetic testing shows that the saturation magnetization ( M s ) decreased obviously from 63.92 to 29.70 A m 2 /kg, while coercivity ( H c ) increased significantly from 288.2 to 740.7 kA/m with increasing Al 3+ ions substitution.