Title :
Optimization of nano-oxide Layer in CIP spin valves
Author :
Qiu, Jinjun ; Luo, Ping ; Li, Kebin ; Zheng, Yuankai ; An, Lihua H. ; Wu, Yihong
Author_Institution :
Data Storage Inst., Singapore, Singapore
fDate :
7/1/2004 12:00:00 AM
Abstract :
The influence of nano-oxide layer (NOL) on interlayer coupling (Hin) and magnetoresistance (MR) of bottom spin-valves (SV) were studied by inserting NOL at four positions: 1) before the Cu spacer; 2) in the middle of the Cu spacer; 3) after the Cu spacer; and 4) after the Cu cap layer. The NOL smoothens the surface of the interface at position 1), 3), and 4), except for 2). Surface flatten by NOL is associated with CoFeOx. Ten percent of MR enhancement can be achieved with NOL at the position 3) and 4). Weak antiferromagnetic interlayer coupling was observed with NOL at position 3). A 27.2% MR ratio has been reached in dual spin valve with two NOLs in two pinned layers.
Keywords :
antiferrimagnetism; magnetic multilayers; magnetoresistance; nanostructured materials; optimisation; spin valves; surface structure; CIP spin valves; CoFeOx; Cu; Cu cap layer; Cu spacer; MR enhancement; bottom spin-valves; dual spin valve; interlayer coupling; magnetoresistance; nano-oxide layer; pinned layers; surface flattening; weak antiferromagnetic coupling; Annealing; Antiferromagnetic materials; Couplings; Magnetic field measurement; Magnetic separation; Magnetoresistance; Memory; Oxidation; Spin valves; Surface topography; Interlayer coupling; MR; NOL; SV; magnetoresistance; nano-oxide layer; spin valve;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2004.829271
