Title :
Recording performance of double-layered perpendicular recording media with an antiferromagnetic layer
Author :
Watanabe, S. ; Takenoiri, S. ; Sakai, Y. ; Enomoto, K. ; Uwazumi, H.
Author_Institution :
Device Technol. Lab., Fuji Electr. Corp. R&D Ltd., Nagano, Japan
Abstract :
For a double-layered perpendicular media having an antiferromagnetic layer, it has been reported that increasing the exchange bias field Hex is effective to reduce spike noise generated from the domain walls of the soft magnetic underlayer (SUL). In this study, a high exchange-coupling energy Jex of 0.345 erg/cm2 was obtained by using the combination of a NiFeB underlayer and a CoFeNiB enhancement layer. By investigating the effects of Hex on the recording performance, it was revealed that increasing Hex caused the writability of a head to deteriorate. However, reducing the nonmagnetic interlayer thickness, which reduces the magnetic spacing between the head and the SUL, could minimize the deterioration in writability. In addition, when the writability was unaffected by Hex, the signal-to-media-noise ratio was improved by the effect of SUL domain noise reduction.
Keywords :
antiferromagnetic materials; boron alloys; cobalt alloys; exchange interactions (electron); ferromagnetic materials; iron alloys; magnetic domain walls; magnetic heads; magnetic multilayers; magnetic recording noise; nickel alloys; perpendicular magnetic recording; soft magnetic materials; CoFeNiB enhancement layer; IrMn; NiFeB underlayer; NiFeB-CoFeNiB; antiferromagnetic layer; domain noise reduction; domain walls; double-layered perpendicular recording media; exchange bias field; head writability; high exchange-coupling energy; magnetic spacing; nonmagnetic interlayer thickness; recording performance; signal-to-media-noise ratio; soft magnetic underlayer; spike noise; Antiferromagnetic materials; Magnetic domain walls; Magnetic domains; Magnetic heads; Magnetic noise; Magnetic recording; Noise generators; Noise reduction; Perpendicular magnetic recording; Soft magnetic materials;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2003.816274
