Crystallographic and magnetic properties of CoAl/sub 0.2/Fe/sub 1.8/O/sub 4/ thin films prepared by a sol-gel method

Abstract

Thin films of Al-substituted cobalt ferrite layers on thermally oxidized silicon wafers were fabricated via the sol-gel method with various annealing temperatures. Structural and magnetic properties of the films were investigated with thermogravimetric and differential thermal analysis (TG-DTA), an x-ray diffractometer, vibrating sample magnetometer (VSM), and atomic force microscopy (AFM). TG-DTA measurements showed exothermic reaction peak at 285/spl deg/C. CoAl/sub 0.2/Fe/sub 1.8/O/sub 4/ thin films that fired at and above 400/spl deg/C had a single cubic spinel structure without any preferred crystallite orientation. Lattice constants monotonically decreased from 0.8381 to 0.8354 nm with increasing annealing temperature from 400 to 800/spl deg/C. As annealing temperature increased from 400 up to 800/spl deg/C, grain size increased from 4.6 to 25.4 nm, whereas the surface roughness was minimized at 700/spl deg/C with a value of 2.0 nm. Parallel and perpendicular coercivity at room temperature showed maximum values of 1980 and 2490 Oe, respectively, in the sample annealed at 700/spl deg/C. Coercivity was shown to be strongly dependent not only on annealing temperature but also on surface roughness.