High-Frequency Magnetic Impedance in (CoFeNi)BSi and (CoFeCrMo)BSi Amorphous Microwires in a Glass Sheath near the Curie Temperature

The temperature behavior of high-frequency magnetoimpedance (MI) in amorphous microwires in a glass sheath has been studied in the temperature range up to the Curie temperature T C . Two alloy samples with compositions of Co 27.4 Fe 5 B 12.26 Si 12.26 Ni 43.08 ( T C ≈ 48°C) and Co 64.82 Fe 3.9 B 10....

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Bibliographic Details
Published in:Physics of metals and metallography 2023, Vol.124 (1), p.1-7
Main Authors: Alam, J., Zedan, A. Kh. Kh, Nematov, M. G., Yudanov, N. A., Kurochka, A. S., Nuriev, A. V., Panina, L. V., Kostishin, V. G.
Format: Article
Language:English
Subjects:
Anisotropy
Chemistry and Materials Science
Curie temperature
Electrical and Magnetic Properties
Frequency ranges
Magnetic anisotropy
Magnetic fields
Magnetoimpedance
Magnetostriction
Materials Science
Metallic Materials
Room temperature
Sheaths
Temperature sensors
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Summary:The temperature behavior of high-frequency magnetoimpedance (MI) in amorphous microwires in a glass sheath has been studied in the temperature range up to the Curie temperature T C . Two alloy samples with compositions of Co 27.4 Fe 5 B 12.26 Si 12.26 Ni 43.08 ( T C ≈ 48°C) and Co 64.82 Fe 3.9 B 10.2 Si 12 Cr 9 Mo 0.08 ( T C ≈ 61°C) with different signs of magnetostriction constant λ s and with different types of magnetic anisotropy were used. For the first alloy sample, λ s < 0, which leads to circular anisotropy. For the second alloy sample, λ s > 0, and easy axis anisotropy is formed along the wire axis. A substantial decrease in the impedance is observed at elevated frequencies with an increase in the temperature in microwires with easy axis anisotropy, regardless of the application of a magnetic field, while the change in the impedance in wires with circular anisotropy is more substantial in the presence of an external field. Moreover, the change in the impedance with an increase in the temperature from room temperature to T C can reach 200–300% in the frequency range of 0.5–0.9 GHz in a magnetic field of about 10 Oe. These results may be of interest for the development of miniature temperature sensors.
ISSN:0031-918X
1555-6190
DOI:10.1134/S0031918X22601998