The influence of field- and stress-induced magnetic anisotropy on the magnetoimpedance in nanocrystalline FeCuNbSiB alloys

Kurlyandskaya, G. V.; Garcı́a-Beneytez, J.M.; Vázquez, M.; Sinnecker, J.P.; Lukshina, V. A.; Потапов, А. П.

doi:10.1063/1.367925

Cited by 54 publications

(24 citation statements)

References 8 publications

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“…Similar peak phenomenon was observed in the uniform wires, ribbons and films, which was attributed to the existence of circumferential or transverse anisotropy and the permeability peak around anisotropy field H K (H K % H P ). [3][4][5][6][7][8] It has been found that in the electrodeposited CoP film there is a transition of magnetic anisotropy with regards to the thickness D of CoP: For D < 0:4 mm, the anisotropy is planar. For 0:4 mm < D < 10 mm it is an oblique anisotropy.…”

Section: Resultsmentioning

confidence: 99%

“…1,2) The GMI effect consists in a magnetic field induced changes in the complex impedance due to the variation of magnetic permeability. Besides of the uniform wires, ribbons and films, [3][4][5][6][7][8] this effect has been observed in inhomogeneous structured materials such as non -magnetic conducting wire plated with magnetic layers and some sandwich films. [9][10][11][12][13][14][15][16][17][18] Large GMI effect occurs at a relative low frequency in BeCu/NiFe, 9) BeCu/CoFeNi, 10) Ag/NiFe 11) and Cu/CoP 12,13) plated wires.…”

Section: Introductionmentioning

confidence: 99%

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Giant Magnetoimpedance in Ti/CoP Plated Wires

Qin

Zhang

et al. 2004

Mater. Trans.

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The giant magnetoimpedance in Ti/CoP plated wires with various CoP thickness was investigated. There is an optimal thickness of CoP magnetic layer for obtaining a large magnetoimpedance. The frequency f Z where the maximum magnetoimpedance ðÁZ=Z 0 Þ max occurs, shifts to low frequency with an increase of CoP thickness. Such shift is correlated with the reduction of the effective critical frequency of skin effect, accompanying the increase of magnetic layer thickness. The magnetic anisotropy field H K for Ti/CoP composite wires depends not only on the radial distance of CoP from the axis of the wire, but also on the CoP thickness.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Giant Magnetoimpedance in Ti/CoP Plated Wires

Qin

Zhang

et al. 2004

Mater. Trans.

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“…5,6) Early works on the MI effect are on the nearly non-magnetostrictive FeCoSiB amorphous wires. [4][5][6] The investigation on the MI effect have been quickly extended to amorphous FeCoSiB ribbons 5,7) and Fe based nanocrystalline ribbons/wires such as FeCuNbSiB, [8][9][10] FeZrB 11,12) and permalloy ribbons/wires NiFeMo. 13,14) In the present work, we report the magnetoimpedance effect in the as cast ribbon Nd 4 Fe 77.5 B 18.5 with melt-spun quenching speed of 40 m/s.…”

Section: )mentioning

confidence: 99%

“…[4][5][6][7][8][9][10][11][12][13][14] The MI effect includes a sensitive change in impedance with the application of a small DC magnetic field. It was suggested that the MI effect strongly depends on the variation in skin depth via the permeability.…”

Section: )mentioning

confidence: 99%

Magnetoimpedance Effect in Amorphous Nd4Fe77.5B18.5 As Cast Ribbon

Qin

2002

Mater. Trans.

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In the present work, the magnetoimpedance effect is reported in as cast Nd 4 Fe 77.5 B 18.5 amorphous ribbon. The magnetoimpedance X (H ))/ X (0) intersect at a frequency. Under a lower field H = 4.22 × 10 3 A·m −1 , the peak frequency f Z is larger than the intersecting frequency f i . Under higher fields H ≥ 6.92×10 3 A·m −1 , the peak frequency f Z coincides with the intersecting frequency f i . Both peak frequency f Z and intersecting frequency f i increase with increasing dc field.

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“…9 Except for varying the composition and geometric structure of the materials, many studies employed field or stress annealing to induce circumferential/transverse magnetic domain structure. 10,11 The most commonly used fabrication methods for composite wires, such as RF sputtering, 20 electroplating 17, 21 and chemical plating, 22,23 cannot control well the magnetic structure. Recently, we imposed a DC current during the process of the chemical plating, and it can significantly improve the GMI effect of composite wire.…”

Section: Introductionmentioning

confidence: 99%

Magnetoimpedance effect of the Ni80Fe20/Cu composite wires: The influence of DC current imposed on the Cu base

Chen

et al. 2014

AIP Advances

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In this paper, the copper composite wires of 75 μm in diameter with a sputtered layer of Ni80Fe20 permalloy were prepared, with a DC current applied to the basal Cu terminals during the fabrication process. The influence of the DC current on the magnetic configuration and Magneto-Impedance (MI) effect was studied. The results indicate that both the current amplitude and actuation duration have significant effect on the magnetic properties of the Ni80Fe20 layer. With appropriate current applied, the induced magnetic field leads to a circumferential magnetic domain structure and reduces significantly the equivalent anisotropy field of Ni80Fe20 layer. Then, the GMI ratio of the composite wires was significantly increased. A maximum GMI of 194.8% can be reached when the current was fixed at 100 mA and the Ni80Fe20 thickness is 780 nm. If the Ni80Fe20 thickness is above 780 nm, the coercivity of the coating layer increases while the GMI ratio of the composite wire reduces, since the magnetic anisotropy of the Ni80Fe20 layer varies from circumferential to longitudinal. The results were explained combining the thermal and magnetic effects of current.

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The influence of field- and stress-induced magnetic anisotropy on the magnetoimpedance in nanocrystalline FeCuNbSiB alloys

Cited by 54 publications

References 8 publications

Giant Magnetoimpedance in Ti/CoP Plated Wires

Giant Magnetoimpedance in Ti/CoP Plated Wires

Magnetoimpedance Effect in Amorphous Nd<SUB>4</SUB>Fe<SUB>77.5</SUB>B<SUB>18.5</SUB> As Cast Ribbon

Magnetoimpedance effect of the Ni80Fe20/Cu composite wires: The influence of DC current imposed on the Cu base

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