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Combined first-order reversal curve and x-ray microscopy investigation of magnetization reversal mechanisms in hexagonal antidot lattices

2016

Article

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The magnetization reversal in nanoscaled antidot lattices is widely investigated to understand the tunability of the magnetic anisotropy and the coercive field through nanostructuring of thin films. By investigating highly ordered focused ion beam milled antidot lattices with a combination of first-order reversal curves and magnetic x-ray microscopy, we fully elucidate the magnetization reversal along the distinct orientations of a hexagonal antidot lattice. This combination proves especially powerful as all partial steps of this complex magnetization reversal can be identified and subsequently imaged. Through this approach we discovered several additional steps that were neglected in previous studies. Furthermore, by imaging the microscopic magnetization state during each reversal step, we were able to link the coercive and interaction fields determined by the first-order reversal curve method to true microscopic magnetization configurations and determine their origin.

Author(s): Gräfe, J. and Weigand, M. and Stahl, C. and Träger, Nick-André and Kopp, M. and Schütz, G. and Goering, E. J. and Haering, F. and Ziemann, P. and Wiedwald, U.
Journal: {Physical Review B}
Volume: 93
Number (issue): 1
Year: 2016
Publisher: American Physical Society

Department(s): Modern Magnetic Systems
Research Project(s): Magnetism in Antidot Lattices
First-Order Reversal Curves
Bibtex Type: Article (article)

Address: Woodbury, NY
DOI: 10.1103/PhysRevB.93.014406
Language: eng

BibTex

@article{escidoc:0073,
  title = {{Combined first-order reversal curve and x-ray microscopy investigation of magnetization reversal mechanisms in hexagonal antidot lattices}},
  author = {Gr\"afe, J. and Weigand, M. and Stahl, C. and Tr\"ager, Nick-Andr\'e and Kopp, M. and Sch\"utz, G. and Goering, E. J. and Haering, F. and Ziemann, P. and Wiedwald, U.},
  journal = {{Physical Review B}},
  volume = {93},
  number = {1},
  publisher = {American Physical Society},
  address = {Woodbury, NY},
  year = {2016},
  doi = {10.1103/PhysRevB.93.014406}
}