Title :
Effect of rapid thermal heating on the unidirectional exchange anisotropy of Ni81Fe19/FeMn system with very thin Ni81Fe19 layers
Author :
Pan, G. ; Huo, S. ; Mapps, D.J. ; Clegg, W. ; Buckley, R.A.
Author_Institution :
CRIST, Plymouth Univ., UK
fDate :
9/1/1999 12:00:00 AM
Abstract :
The unidirectional exchange anisotropy field, Hua, of NiFe(tNiFe)/FeMn(15 nm) with very small tNiFe from 3 nm to 25 nm was studied by heating the NiFe films using an in-situ rapid thermal heater during sputtering. A critical NiFe film thickness of about 15 nm was found. When tNiFe was below 15 nm, the H ua of NiFe/FeMn films was enhanced by in-situ heating, compared with that of films deposited without heating. However, no significant difference of Hua between the films with and without in-situ heating were observed for films with NiFe film thicker than 15 nm and the dependence of Hua on NiFe film thickness roughly obeys 1/tNiFe dependence. X-ray diffraction examination of these films suggests that a better epitaxial growth and improved crystallinity of the γ-FeMn(111)/NiFe(111) might be responsible for the enhanced Hua at NiFe/FeMn interface
Keywords :
X-ray diffraction; coercive force; exchange interactions (electron); ferromagnetic materials; heat treatment; iron alloys; magnetic epitaxial layers; magnetic multilayers; manganese alloys; nickel alloys; sputter deposition; FeMn; Ni81Fe19; Ni81Fe19/FeMn system; NiFe/FeMn interface; X-ray diffraction; critical NiFe film thickness; crystallinity; epitaxial growth; rapid thermal heating; sputtering; unidirectional exchange anisotropy; very thin Ni81Fe19 layers; Anisotropic magnetoresistance; Glass; Heat engines; Heating; Iron; Magnetic films; Sputtering; Substrates; Temperature; X-ray diffraction;
Journal_Title :
Magnetics, IEEE Transactions on
