DocumentCode
3142504
Title
Inducing high coercivity and anisotropy into strained Fe-Co thin films, towards rare earth free permanent magnets applications
Author
Giannopoulos, G. ; Salikhov, R. ; Reichel, L. ; Markou, A. ; Panagiotopoulos, I. ; Farle, M. ; Fahler, S. ; Psycharis, V. ; Niarchos, D.G.
Author_Institution
INN, NCSR Demokritos, Athens, Greece
fYear
2015
fDate
11-15 May 2015
Firstpage
1
Lastpage
1
Abstract
The present study is focused on our effort towards high performance permanent magnets with no rare earth elements. For this reason, high magnetization FeCo system is proposed as an alternative candidate. High magneto-crystalline anisotropy along with high magnetic moment is required for permanent magnets. According to theoretical calculations FeCo alloy can support large uniaxial magnetic anisotropy energy (MAE), Ku and saturation magnetization Ms, while tetragonal distortion can be induced via coherent growth of Fe-Co layers on different substrate or buffer materials. Based on a combinatorial exploration of AuCu underlayer lattice constant we employed AuCu as a buffer layer in our system. Adding a third element, e.g. Carbon, was recently proposed to stabilize the strain in Fe-Co, preventing the complete lattice relaxation of the system, while an increased magnetocrystalline anisotropy was observed in FeCoC thin films. We report giant perpendicular anisotropy in our thin magnetic films in the excess of 1MJ/m3, confirmed by FMR measurements and coercivity induction of almost 850Oe in our multilayers films approach.
Keywords
buffer layers; carbon; cobalt alloys; coercive force; copper alloys; ferromagnetic materials; ferromagnetic resonance; gold alloys; iron alloys; magnetic multilayers; magnetic thin films; metallic thin films; permanent magnets; perpendicular magnetic anisotropy; FMR measurements; FeCoC-AuCu; buffer layer; buffer materials; coercivity induction; coherent growth; giant perpendicular anisotropy; magnetic moment; magnetocrystalline anisotropy; multilayer films; rare earth free permanent magnet applications; saturation magnetization; strained thin films; tetragonal distortion; thin magnetic films; underlayer lattice constant; uniaxial magnetic anisotropy energy; Anisotropic magnetoresistance; Iron; Magnetic multilayers; Magnetic resonance; Magnetometers; Perpendicular magnetic recording; Saturation magnetization;
fLanguage
English
Publisher
ieee
Conference_Titel
Magnetics Conference (INTERMAG), 2015 IEEE
Conference_Location
Beijing
Print_ISBN
978-1-4799-7321-7
Type
conf
DOI
10.1109/INTMAG.2015.7157630
Filename
7157630
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