Open AccessThe breakdown of the fingerprinting of vortices by hysteresis loops in circular multilayer ring arrays
Author(s) -
Volker Rose,
Xuemei Cheng,
D. J. Keavney,
J. W. Freeland,
Kristen Buchanan,
B. Ilic,
V. Metlushko
Publication year - 2007
Publication title -
applied physics letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.182
H-Index - 442
eISSN - 1077-3118
pISSN - 0003-6951
DOI - 10.1063/1.2786856
Subject(s) - remanence , condensed matter physics , magnetic hysteresis , hysteresis , microscale chemistry , ferromagnetism , materials science , magnetic flux , vortex , micromagnetics , magnetization , demagnetizing field , vortex state , magnetic force microscope , magnetic field , physics , superconductivity , mechanics , mathematics education , mathematics , quantum mechanics
Microscale single-layer ferromagnetic rings typically exhibit a magnetic vortex state at remanence, characterized by a flux-closed magnetic state with zero stray fields. Magnetic reversal in such systems yields a vanishing remanent magnetization. In contrast, the authors show that in individual layers in thin rings, which alternate magnetic and nonmagnetic materials (NiFe∕Cu∕Co), layer-resolved hysteresis loops, measured using x-ray resonant magnetic scattering, exhibit the characteristics of a vortex formation, although photoelectron emission microscopy and micromagnetic simulations clearly prove that multidomain states are formed. This result is of considerable importance for the development of pseudo-spin-valve-type structures for applications.
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