Abstract
Investigation of magnetic properties and nanostructure of stacked media with a CoPt-B2O3 granular recording layer (GRL) and granular cap layers (CL) with CoPt and a typical ferromagnetic oxide of rare earth (RE) oxide (RE oxide: Gd2O3, Nd2O3, Sm2O3, and CeO2) are reported. CoPt-RE oxide granular layer shows higher saturation magnetization and magnetic anisotropy than that of CoPtCrB continuous layer. In stacked media with CoPt-Gd2O3 granular CL (9 nm), nucleation field increases from 0.7 to 0.8 kOe and saturation field decreases from 21.5 to 12.5 kOe with comparable values to those of CoPtCrB continuous CL. This indicates that CoPt-RE oxide granular CL is effective to control intergranular exchange coupling. Reduction of coercivity distribution ratio (∆Hc/Hc) from 0.15 to 0.09 which is comparable to that of CoPtCrB continuous CL when CoPt-Gd2O3 granular CL thickness is changed from 4 to 9 nm is observed. This means CoPt-Gd2O3 granular CL is effective to reduce switching field distribution. Furthermore, significant reduction of surface roughness (Ra) for media with CoPt-Gd2O3 granular CL (9 nm) from 0.32 to 0.25 nm is observed. This reveals that CoPt-RE oxide granular CL has a great impact to induce stacked media with flat surface. Based on the cross-section observation by TEM, the media with CoPt-Gd2O3 granular CL shows continuous structure of grain boundaries from the GRL up to the CL and which results in one-on-one growth of magnetic grain with homogeneous columnar structure. Focusing on the surface morphology, media with CoPt-Gd2O3 granular CL shows smoother surface than that of media with CoPtCrB continuous CL which supports the Ra evaluation result. These results indicate that the employment of granular CoPt-RE oxide for CL is not only to reduce switching field distribution but also to flatten surface of the stacked media.
Highlights
Since the first hard disk drive with perpendicular magnetic recording was commercialized, a stacked medium with a granular recording layer (GRL) and a cap layer (CL) has been adopted
Based on the cross-section observation by transmission electron microscopy (TEM), the media with CoPt-Gd2O3 granular cap layers (CL) shows continuous structure of grain boundaries from the GRL up to the CL and which results in one-on-one growth of magnetic grain with homogeneous columnar structure
Focusing on the surface morphology, media with CoPt-Gd2O3 granular CL shows smoother surface than that of media with CoPtCrB continuous CL which supports the Ra evaluation result. These results indicate that the employment of granular CoPt-rare earth (RE) oxide for CL is to reduce switching field distribution and to flatten surface of the stacked media
Summary
Since the first hard disk drive with perpendicular magnetic recording was commercialized, a stacked medium with a granular recording layer (GRL) and a cap layer (CL) has been adopted. Many authors have proposed various continuous layer materials with low magnetic anisotropy (Ku) and strong intergranular exchange coupling for the CLs such as, Co/Pd multilayers, rare earth (RE) metal alloy layers, and CoPtCrB alloy layers.. Many authors have proposed various continuous layer materials with low magnetic anisotropy (Ku) and strong intergranular exchange coupling for the CLs such as, Co/Pd multilayers, rare earth (RE) metal alloy layers, and CoPtCrB alloy layers.11 In these CLs, precise control of intergranular exchange coupling is quite challenging due to inhomogeneous nanostructure in the thickness direction of the continuous CLs deposited on metaloxide phase separated nanostructure of GRL.. To increase thermal stability of the recording media, the employment of material with high Ku is required To solve these issues, we propose a new granular-type CL consisting of high Ku CoPt grains and ferromagnetic oxide grain boundaries. We will discuss about magnetic properties and nanostructure of the stacked media with the new CL
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