Mechanical properties and internal quenching stresses in Co-rich amorphous ferromagnetic microwires

Mechanical properties and internal quenching stresses in Co-rich amorphous ferromagnetic microwires

The whole set of geometrical, mechanical and magnetic parameters of Co-rich amorphous ferromagnetic microwires very promising for the development of sensitive stress and Giant Magneto-Impedance sensors have been determined by means of scanning electron microscopy, selective nanoindentation and small...

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Bibliographic Details
Published in:Journal of alloys and compounds Vol. 707; pp. 199 - 204
Main Authors: Kostitsyna, E.V., Gudoshnikov, S.A., Popova, A.V., Petrzhik, M.I., Tarasov, V.P., Usov, N.A., Ignatov, A.S.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 15-06-2017
Elsevier BV
Subjects:
Amorphous ferromagnetic microwire
Ferromagnetism
Giant magnetoimpedance
Magnetic properties
Magnetostriction
Mechanical properties
Nanoindentation
Quenching
Residual quenching stress
Residual stress
Scanning electron microscopy
Sensor applications
Viscoelasticity
Mechanical properties
Amorphous ferromagnetic microwire
Residual quenching stress
Sensor applications
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Summary:The whole set of geometrical, mechanical and magnetic parameters of Co-rich amorphous ferromagnetic microwires very promising for the development of sensitive stress and Giant Magneto-Impedance sensors have been determined by means of scanning electron microscopy, selective nanoindentation and small angle magnetization rotation method. The magnetostriction constants obtained are sensitive to the true microwire compositions. The experimentally estimated amplitudes of the residual quenching stress are mainly determined by the ratio of the inner and outer wire diameters. They are found to be in good correspondence with the theoretical values calculated based on the theory of viscoelasticity. •Co-rich amorphous microwires were fabricated by Taylor- Ulitovsky technique.•Young modulus and hardness of microwires were measured by selective nanoindentation.•Residual quenching stress were determined by SAMR method.•Magnetostriction constants were determined by SAMR method.•Experimental results were compared with theoretical estimates.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2016.11.387