Multisegmented Nanowires: a Step towards the Control of the Domain Wall Configuration

Cylindrical nanowires synthesized by controlled electrodeposition constitute excellent strategic candidates to engineer magnetic domain configurations. In this work, multisegmented CoNi/Ni nanowires are synthesized for tailoring a periodic magnetic structure determined by the balance between magneto...

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Veröffentlicht in:	Scientific reports 2017-09, Vol.7 (1), p.11576-8, Article 11576
Hauptverfasser:	Berganza, E., Jaafar, M., Bran, C., Fernández-Roldán, J. A., Chubykalo-Fesenko, O., Vázquez, M., Asenjo, A.
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Sprache:	eng
Schlagworte:	639/301/357/997 639/925/357/1016 Electron diffraction Electron microscopy Electrons Humanities and Social Sciences Magnetic fields Magnetism multidisciplinary Nanotechnology Nanowires Science Science (multidisciplinary) Transmission electron microscopy
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description	Cylindrical nanowires synthesized by controlled electrodeposition constitute excellent strategic candidates to engineer magnetic domain configurations. In this work, multisegmented CoNi/Ni nanowires are synthesized for tailoring a periodic magnetic structure determined by the balance between magnetocrystalline and magnetostatic energies. High-resolution Transmission Electron Microscopy confirms the segmented growth and the sharp transition between layers. Although both CoNi and Ni segments have similar fcc cubic crystal symmetry, their magnetic configuration is quite different as experimentally revealed by Magnetic Force Microscopy (MFM) imaging. While the Ni segments are single domain with axial magnetization direction, the CoNi segments present two main configurations: a single vortex state or a complex multivortex magnetic configuration, which is further interpreted with the help of micromagnetic simulations. This original outcome is ascribed to the tight competition between anisotropies. The almost monocrystalline fcc structure of the CoNi segments, as revealed by the electron diffraction patterns, which is atypical for its composition, contributes to balance the magnetocrystalline and shape anisotropies. The results of MFM measurements performed under in-plane magnetic field demonstrate that it is possible to switch from the multivortex configuration to a single vortex configuration with low magnetic fields.
doi_str_mv	10.1038/s41598-017-11902-w
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While the Ni segments are single domain with axial magnetization direction, the CoNi segments present two main configurations: a single vortex state or a complex multivortex magnetic configuration, which is further interpreted with the help of micromagnetic simulations. This original outcome is ascribed to the tight competition between anisotropies. The almost monocrystalline fcc structure of the CoNi segments, as revealed by the electron diffraction patterns, which is atypical for its composition, contributes to balance the magnetocrystalline and shape anisotropies. 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subjects	639/301/357/997 639/925/357/1016 Electron diffraction Electron microscopy Electrons Humanities and Social Sciences Magnetic fields Magnetism multidisciplinary Nanotechnology Nanowires Science Science (multidisciplinary) Transmission electron microscopy
title	Multisegmented Nanowires: a Step towards the Control of the Domain Wall Configuration
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