Open AccessCoercivity of domain-wall motion in thin films of amorphous rare-earth–transition-metal alloys
Author(s) -
Masud Mansuripur,
Roscoe Giles,
G.N. Patterson
Publication year - 1991
Publication title -
journal of applied physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.699
H-Index - 319
eISSN - 1089-7550
pISSN - 0021-8979
DOI - 10.1063/1.348250
Subject(s) - condensed matter physics , amorphous solid , dipole , coercivity , thin film , materials science , anisotropy , lattice (music) , magnetic dipole , magnetic domain , amorphous metal , domain wall (magnetism) , magnetic field , physics , optics , chemistry , magnetization , nanotechnology , crystallography , quantum mechanics , acoustics
Computer simulations of a two‐dimensional lattice of magnetic dipoles are performed on the Connection Machine. The lattice is a discrete model for thin films of amorphous rare‐earth–transition‐metal alloys with application to erasable optical data‐storage systems. Simulated dipoles follow the dynamic equation of Landau, Lifshitz, and Gilbert under the influence of an effective magnetic field arising from local anisotropy, near‐neighbor exchange, classical dipole‐dipole interactions, and externally applied fields. By introducing several types of defects and inhomogeneities in the lattice, we show that the motion of domain walls can be hampered in various ways and to varying degrees.
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