Strain Engineering of Magnetic Anisotropy in Epitaxial Films of Cobalt Ferrite

Abstract

Perpendicular magnetic anisotropy (PMA) energy up to Ku=6.10.8 MJ m-3 is demonstrated in this study by inducing large lattice-distortion exceeding 3% at room temperature in epitaxially distorted cobalt ferrite Co x Fe 3-x O 4 (x = 0.72) (001) thin films. Although the thin film materials include no rare-earth elements or noble metals, the observed Ku is larger than that of the neodymium-iron-boron compounds for high-performance permanent magnets. The large PMA is attributed to the significantly enhanced magneto-elastic effects, which are pronounced in distorted films with epitaxial lattice structures upon introducing a distortion control layer of composition Mg 2-x Sn1+xO 4 . Surprisingly, the induced Ku can be quantitatively explained in terms of the agreement between the local crystal field of Co 2+ and the phenomenological magneto-elastic model, indicating that the linear response of induced Ku is sufficiently valid even under lattice distortions as large as 3.2%. Controlling tetragonal lattice deformation using a non-magnetic spinel layer for ferrites could be a promising protocol for developing materials with large magnetic anisotropies.

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