Magnetic behavior of the amorphous wires covered by glass

Chiriac, H.; Pop, Gheorghe Ioan; Barariu, F.; Vázquez, M.

doi:10.1063/1.356791

Cited by 32 publications

(3 citation statements)

References 8 publications

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“…Such microwires present peculiar magnetic properties, like spontaneous magnetic bistability in Fe-rich compositions and giant magnetoimpedance effect in Co-based alloys, being intensively studied for sensor applications [1][2][3]. Their amorphous character is achieved by the high quenching rate (about 10 4 -10 7 K/s) due to the introduction of the water jet during the pulling of the microwire.…”

Section: Introductionmentioning

confidence: 99%

Studies of magnetoresistance and structure in Co‐Ni‐Cu thin wires

Zhukov

Marero

Batallán

et al. 2004

phys. stat. sol. (c)

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We report on studies of magneto-transport properties and structure (by neutron and X-ray diffraction techniques) at 5-300K in glass coated Co 29 Ni 25 Mn 1 Cu 45 microwires prepared by the Taylor-Ulitovsky technique. Annealing of the sample (973 K during 1 hour) results in an increasing of room temperature coercivity (H c ) from 65 Oe up to 800 Oe. Considerable magneto-resistance, MR, is found in both in asprepared and annealed microwires increasing up to about 4% in the annealed samples. Magnetic field dependence of MR in as-prepared and annealed samples is quite different. Roughly monotonic decay is observed in as-prepared microwires. Annealed sample exhibits a maximum and considerable hysteresis on magnetic field dependence of MR. Neutron diffraction allows to distinguish two peaks in the as-prepared sample and 3 peaks in annealed samples. Observed changes in temperature dependence of magnetic properties and of MR are correlated to the structure changes with temperature.

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Section: Introductionmentioning

confidence: 99%

Studies of magnetoresistance and structure in Co‐Ni‐Cu thin wires

Zhukov

Marero

Batallán

et al. 2004

phys. stat. sol. (c)

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“…In the last few years, this technique has been developed to produce ferromagnetic microwires with amorphous structure, which make them to be attractive notably because of their outstanding soft magnetic properties. The general composition is (Fe,-Co,Ni,Mn)(Si,B) exhibiting a coercive field, H c ; of the order of 0.1-10 Oe [2,3]. Such microwires present peculiar magnetic properties, like spontaneous magnetic bistability in Fe-rich compositions and giant magnetoimpedance effect in Co-based alloys, being intensively studied for sensor applications in the last years [2][3][4][5].…”

mentioning

confidence: 99%

“…The general composition is (Fe,-Co,Ni,Mn)(Si,B) exhibiting a coercive field, H c ; of the order of 0.1-10 Oe [2,3]. Such microwires present peculiar magnetic properties, like spontaneous magnetic bistability in Fe-rich compositions and giant magnetoimpedance effect in Co-based alloys, being intensively studied for sensor applications in the last years [2][3][4][5]. Their amorphous character is achieved by the high quenching rate due to introduction of the water jet during the pulling of the microwire.…”

mentioning

confidence: 99%

Magnetoresistance in Co–Ni–Cu glass coated microwires

Zhukov¹,

Luna

Martinez

et al. 2004

Journal of Magnetism and Magnetic Materials

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Advanced Magnetic Microwires

Vázquez

2007

Handbook of Magnetism and Advanced Magnetic Materials

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The most relevant aspects of magnetic amorphous microwires are collected in this chapter from production and processing methods to micromagnetic magnetization reversal processes, including selected technological applications finally paying particular attention to the actual search for novel microwire materials. After a first general review of the present state of the art in Section 1, the fabrication of amorphous and nanocrystalline microwires by rapid solidification techniques and subsequent processing is described in Section 2, including important characteristics such as mechanical stress distribution. Section 3 reviews the most interesting magnetic features of positive magnetostriction, Fe‐based microwires with bistable magnetic behavior such as: domain structure, magnetization reversal mechanism and its dynamics, magnetoelastic behavior, magnetostatic interactions in arrays of bistable microwires, and applications. Section 4 is devoted to the circular magnetization process and magnetoimpedance effect of nonmagnetostrictive microwires, the microwave properties, and their applications. Finally, Section 5 summarizes the latest results obtained in the search for novel microwires with new and/or optimized properties: nanocomposite and multilayer microwires.

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Magnetic behavior of the amorphous wires covered by glass

Cited by 32 publications

References 8 publications

Studies of magnetoresistance and structure in Co‐Ni‐Cu thin wires

Studies of magnetoresistance and structure in Co‐Ni‐Cu thin wires

Magnetoresistance in Co–Ni–Cu glass coated microwires

Advanced Magnetic Microwires

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