Interparticle interaction and magnetic anisotropy in vacuum evaporated Co–O perpendicular magnetic thin film

Interparticle interactions in perpendicularly and longitudinally oriented Ba-ferrite particulate media are studied experimentally. In order to make clear the effect of the orientation on the interparticle interactions in the media, the angular dependence of the interaction fields is measured by compensating for the demagnetizing fields at each measurement direction. It is found that perpendicularly and longitudinally oriented Ba-ferrite particulate media exhibit quite different angular dependence of the interaction fields, even though both of the media were prepared using the same dispersion. The study of the magnetic anisotropy derived from the interparticle interactions, which is significantly sensitive to the arrangement of the particles in the media, is considered to be useful for estimating the morphology of the magnetic layer of the media.

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Magnetic anisotropy derived from interparticle interactions in CoPtCr/SiO2 granular thin film longitudinal media

Tateno

Katakura

Igari

et al. 2003

Journal of Applied Physics

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High field ferromagnetic resonance measurements of the anisotropy field of longitudinal recording thin-film media Magnetic and structural properties of hexagonal-close-packed-CoCrPt-C granular media for high areal density recordingThe magnetic anisotropy derived from interparticle interactions in a CoPtCr/SiO 2 granular thin film longitudinal medium has been experimentally studied. In order to clarify the effect of magnetostatic interactions between particles in the medium, the angular dependence of the interaction fields has been investigated. The interaction fields in the medium were obtained from the remanent magnetization curves measured in several directions in the plane normal to the medium plane by compensating for the demagnetizing fields at each measurement direction. It has been shown that the interparticle interactions in the medium exhibit clear anisotropy, which is related to the magnetostatic interactions. As a result, the intrinsic magnetic anisotropy of the medium has been quantitatively separated into two contributions, the magnetic interaction anisotropy between particles and the anisotropy of each particle. The magnetic anisotropy caused by the interparticle interactions in the medium plays an important role in the thermal stability of the magnetization in the recorded media, in the minor-loop magnetizing process and in the recording process of the medium when using a ring-type head.

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Interparticle interaction and magnetic anisotropy in vacuum evaporated Co–O perpendicular magnetic thin film

Cited by 4 publications

References 14 publications

Magnetic interaction fields and switching field distribution in metal evaporated tape

Magnetic interaction fields and switching field distribution in metal evaporated tape

Interparticle interactions in perpendicularly and longitudinally oriented Ba-ferrite particulate media

Magnetic anisotropy derived from interparticle interactions in CoPtCr/SiO2 granular thin film longitudinal media

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