Preparation of short-period Fe-N magnetic multilayers using an atomic nitrogen beam

Preparation of short-period Fe-N magnetic multilayers using an atomic nitrogen beam

Magnetic multilayers containing Fe-N layers with bilayer periods of between /spl sim/15-84 /spl Aring/ and sharp interfaces, are successfully grown using an atomic (free radical) nitrogen beam. The phase composition and microstructure is found to be a function of the initial Fe layer thickness prior...

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Veröffentlicht in:IEEE transactions on magnetics 2001-07, Vol.37 (4), p.2308-2310
Hauptverfasser: Telling, N.D., Bonder, M.J., Jones, G.A., Faunce, C.A., Grundy, P.J., Lord, D.G., Joyce, D.E.
Format: Artikel
Sprache:eng
Schlagworte:
Anisotropic magnetoresistance
Anisotropy
Atomic beams
Atomic layer deposition
Atomic measurements
Beams (radiation)
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Exact sciences and technology
Free radicals
Interfacial magnetic properties (multilayers, magnetic quantum wells, superlattices, magnetic heterostructures)
Iron
Lattices
Magnetic multilayers
Magnetic properties and materials
Magnetic properties of surface, thin films and multilayers
Magnetism
Microstructure
Multilayers
Nitrogen
Nonhomogeneous media
Origins
Physics
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Zusammenfassung:Magnetic multilayers containing Fe-N layers with bilayer periods of between /spl sim/15-84 /spl Aring/ and sharp interfaces, are successfully grown using an atomic (free radical) nitrogen beam. The phase composition and microstructure is found to be a function of the initial Fe layer thickness prior to nitrogenation. Generally, higher N content phases are found as the initial Fe layer is reduced. Small grains (/spl sim/10 nm) are observed in multilayers containing /spl alpha/-Fe and /spl gamma/-Fe/sub 4/N phases. In these films, a perpendicular anisotropy is found for a certain thickness of the Fe layers. A stripe domain structure associated with this anisotropy is observed. The origin of this anisotropy may be induced stress caused by lattice mismatch between layers and/or lattice dilation due to N incorporation.
ISSN:0018-9464
1941-0069
DOI:10.1109/20.951156