Title :
2.5-inch disk patterned media prepared by an artificially assisted self-assembling method
Author :
Naito, Katsuyuki ; Hieda, Hiroyuki ; Sakurai, Masatoshi ; Kamata, Yoshiyuki ; Asakawa, Koji
Author_Institution :
Storage Mater. & Devices Lab., Toshiba Corp., Kawasaki, Japan
fDate :
9/1/2002 12:00:00 AM
Abstract :
Circumferential magnetic patterned media were prepared on a 2.5-inch-diameter glass plate and on a 3-in-diameter silicon plate. A Ni master disk possessing spiral patterns with 60-250-nm-width lands and a 400-nm-width groove was pressed into a resist film on a CoPt or CoCrPt film to transfer the spiral patterns. A diblock copolymer solution was cast into the obtained grooves and then annealed to prepare self-assembling dot structures aligned along the grooves. According to the dot patterns, the underlying magnetic films were patterned by ion milling to yield patterned media with a 40-nm diameter. Coercive forces and squareness ratios of the patterned media increased compared to those of the continuous media, probably due to the decrement of a demagnetizing field. Single magnetic domains with an almost perpendicular orientation were confirmed in each magnetic dot.
Keywords :
coercive force; ion beam applications; magnetic domains; magnetic hysteresis; magnetic recording; magnetic thin films; nanotechnology; polymer blends; self-assembly; 2.5 inch; 3 in; 40 nm; 400 nm; 60 to 250 nm; CoCrPt; CoCrPt film; CoPt; CoPt film; Ni; Ni master disk; artificially assisted self-assembling method; circumferential magnetic patterned media; coercive forces; demagnetizing field decrement; diblock copolymer solution; dot patterns; glass plate; groove width; ion milling; land width; magnetic film patterning; magnetic nanostructures; nanoimprint; perpendicular orientation single magnetic domains; resist film; self-assembling dot structures; silicon plate; spiral pattern transfer; spiral patterns; squareness ratios; Annealing; Grain size; Magnetic domains; Magnetic films; Milling; Perpendicular magnetic recording; Resists; Self-assembly; Signal to noise ratio; Spirals;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2002.802847
