Spin-valve thermal stability: interdiffusion versus exchange biasing

Author

Anderson, Geoffrey W. ; Pakala, Mahendra ; Huai, Yiming

Volume

36

Issue

5

fYear

2000

fDate

9/1/2000 12:00:00 AM

Firstpage

2605

Lastpage

2607

Abstract

This paper focuses on the roles of exchange biasing and interdiffusion on the thermal stability of different spin-valve structures. The thermal stability of the exchange field was found to be an intrinsic property of the antiferromagnet structure-it is not significantly effected by roughness or the quality of crystalline texture in the spin-valve. Two routes for interdiffusion were observed: mixing at the Ta/NiFe interface and Mn interdiffusion into the pinned layer and beyond. Synthetic spin-valves showed improved thermal stability as the Ru layer acts as a barrier against Mn interdiffusion. Annealing the PtMn spin-valves significantly reduced interdiffusion, inducing a phase transition to the more stable PtMn fct state and passivating the Ta/NiFe intermixing

Keywords

annealing; antiferromagnetic materials; chemical interdiffusion; diffusion barriers; exchange interactions (electron); spin valves; thermal stability; PtMn; Ru; Ta-NiFe; annealing; antiferromagnet structure; crystalline texture; diffusion barrier; exchange biasing; interdiffusion; interface roughness; phase transition; spin valve; thermal stability; Annealing; Crystallization; Magnetic films; Magnetic heads; Magnetic recording; Magnetic sensors; Temperature sensors; Thermal sensors; Thermal stability; Through-silicon vias;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/20.908530

Filename

908530