Reversal modes in FeCoNi nanowire arrays: Correlation between magnetostatic interactions and nanowires length
FeCoNi nanowire arrays (175nm in diameter and lengths ranging from 5 to 40μm) were fabricated into nanopores of hard-anodized aluminum oxide templates using pulsed ac electrodeposition technique. Increasing the length had no considerable effect on the composition and crystalline characteristics of F...
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Veröffentlicht in: | Journal of magnetism and magnetic materials 2015-03, Vol.378, p.73-83 |
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Sprache: | eng |
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Zusammenfassung: | FeCoNi nanowire arrays (175nm in diameter and lengths ranging from 5 to 40μm) were fabricated into nanopores of hard-anodized aluminum oxide templates using pulsed ac electrodeposition technique. Increasing the length had no considerable effect on the composition and crystalline characteristics of Fe47Co38Ni15 nanowires (NWs). By eliminating the dendrites formed at the bottom of the pores, we report a careful investigation on the effect of magnetostatic interactions on magnetic properties and the effect of nanowire length on reversal modes. Hysteresis loop measurements indicated that increasing the length decreases coercivity and squareness values. On the other hand, first-order reversal curve measurements show a linear correlation between the magnetostatic interactions and length of NWs. Comparing reversal modes of the NWs both experimentally and theoretically using angular dependence of coercivity, we find that when L≤22μm, a vortex domain wall mode is only occurred. When L>22μm, a non-monotonic behavior indicates a transition from the vortex to transverse domain wall propagation. As a result, a critical length was found above which the transition between the reversal modes is occurred due the enhanced interactions. The transition angle also shifts toward a lower angle as the length increases. Moreover, with increasing length from 22 to 31μm, the single domain structure of NWs changes to a pseudo single domain state. A multidomain-like behavior is also found for the longest NWs length.
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•Fabrication of long and uniform FeCoNi NWs into hard-anodized AAO templates.•Investigation of morphology, crystalline and compositional characteristics.•Performing a careful investigation on the magnetic properties of NWs.•Obtaining a linear correlation between magnetostatic interactions and NWs length.•A critical length above which a transition between reversal modes is occurred. |
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ISSN: | 0304-8853 |
DOI: | 10.1016/j.jmmm.2014.10.155 |