Title :
Magnetic microstructure and noise property of electrolessly deposited CoNiFeB SoftMagnetic underlayer
Author :
Sugiyama, Atsushi ; Adachi, Ken ; Sakagami, Mariko ; Yoshino, Masahiro ; Kawaji, Jun ; Asahi, Toru ; Tsumori, Toshihiro ; Osaka, Tetsuya
Author_Institution :
Graduate Sch. of Sci. & Eng., Waseda Univ., Tokyo, Japan
Abstract :
A CoNiFeB soft magnetic underlayer (SUL) was prepared by electroless deposition using dimethylamineborane as the reducing agent. A 2.5-inch NiP/Al disk was used as the substrate, on which a NiP nonmagnetic amorphous-layer was also electrolessly deposited. The coercivity Hc of as-deposited CoNiFeB films in the direction parallel to the surface exhibited a convex-parabolic dependency on the film thickness. The in-plane M-H loops and the two-dimensional Kerr effect images of the CoNiFeB film showed a nearly isotropic character with Hc of 25 Oe and no marked domain boundaries. From magnetic force microscope measurements, we confirmed that these behaviors resulted from the formation of striped magnetic domains caused by slightly perpendicular magnetic anisotropy of SUL. As far as the noise characteristics are concerned, dc noise was increased with Hc, while spike noise was suppressed.
Keywords :
Kerr magneto-optical effect; cobalt alloys; coercive force; electrodeposition; iron alloys; magnetic domains; magnetic force microscopy; magnetic noise; magnetic thin films; nickel alloys; soft magnetic materials; 2.5 inch; 2D Kerr effect; CoNiFeB; M-H loop; NiP-Al; NiP/Al disk; convex-parabolic dependency; dc noise; dimethylamineborane; electroless deposition; film coercivity; isotropic character; magnetic force microscope; magnetic microstructure; noise property; nonmagnetic amorphous layer; reducing agent; slightly perpendicular magnetic anisotropy; soft magnetic underlayer; striped magnetic domain; Amorphous magnetic materials; Coercive force; Magnetic anisotropy; Magnetic films; Magnetic noise; Magnetic properties; Micromagnetics; Perpendicular magnetic anisotropy; Soft magnetic materials; Substrates; CoNiFe; dc noise; electroless deposition; soft magnetic underlayer; spike noise; striped magnetic domain;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2005.855273
