Thermal stability of magnetic properties of nanocrystalline [.sub.88][Hf.sub.4][Mo.sub.2][Zr.sub.1][B.sub.4][Cu.sub.1] alloy with induced magnetic anisotropy

The effect of nanocrystallizing annealing in the presence of an ac magnetic field (magnetic heat treatment) and tensile stresses (thermomechanical treatment), as well as in the presence of both tensile stresses and an ac magnetic field (complex thermomechanical magnetic treatment) on the magnetic pr...

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Published in:Physics of metals and metallography 2016-10, Vol.117 (10), p.976
Main Authors: Dmitrieva, N.V, Lukshina, V.A, Filippov, B.N, Potapov, A.P
Format: Article
Language:English
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Alloys
Analysis
Anisotropy
Annealing
Magnetic fields
Magnetic properties
Specialty metals industry
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Lukshina, V.A
Filippov, B.N
Potapov, A.P
description The effect of nanocrystallizing annealing in the presence of an ac magnetic field (magnetic heat treatment) and tensile stresses (thermomechanical treatment), as well as in the presence of both tensile stresses and an ac magnetic field (complex thermomechanical magnetic treatment) on the magnetic properties of the nanocrystalline [([Fe.sub.0.7][Co.sub.0.3]).sub.88][Hf.sub.4][Mo.sub.2][Zr.sub.1][B.sub.4][Cu.sub.1] alloy and their thermal stability has been studied. It has been found that the nanocrystallization of the studied [([Fe.sub.0.7][Co.sub.0.3]).sub.88][Hf.sub.4][Mo.sub.2][Zr.sub.1][B.sub.4][Cu.sub.1] alloy in the course of magnetic heat treatment, thermomechanical treatment, and thermomechanical magnetic treatment at low tensile stresses (6-30 MPa) leads to about a threefold decrease in the coercive force, but does not ensure the thermal stability of magnetic properties at high temperatures. In nanocrystallization, in the course of thermomechanical treatment at 620[degrees]C for 20 min under tensile stresses [sigma] = 250 MPa has been found to be optimum for the high-temperature application (up to 550[degrees]C) of the studied alloy. Keywords: nanocrystalline Fe- and Co-based alloy, magnetic properties, thermal stability, magnetic anisotropy
doi_str_mv 10.1134/S0031918X16100057
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It has been found that the nanocrystallization of the studied [([Fe.sub.0.7][Co.sub.0.3]).sub.88][Hf.sub.4][Mo.sub.2][Zr.sub.1][B.sub.4][Cu.sub.1] alloy in the course of magnetic heat treatment, thermomechanical treatment, and thermomechanical magnetic treatment at low tensile stresses (6-30 MPa) leads to about a threefold decrease in the coercive force, but does not ensure the thermal stability of magnetic properties at high temperatures. In nanocrystallization, in the course of thermomechanical treatment at 620[degrees]C for 20 min under tensile stresses [sigma] = 250 MPa has been found to be optimum for the high-temperature application (up to 550[degrees]C) of the studied alloy. 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It has been found that the nanocrystallization of the studied [([Fe.sub.0.7][Co.sub.0.3]).sub.88][Hf.sub.4][Mo.sub.2][Zr.sub.1][B.sub.4][Cu.sub.1] alloy in the course of magnetic heat treatment, thermomechanical treatment, and thermomechanical magnetic treatment at low tensile stresses (6-30 MPa) leads to about a threefold decrease in the coercive force, but does not ensure the thermal stability of magnetic properties at high temperatures. In nanocrystallization, in the course of thermomechanical treatment at 620[degrees]C for 20 min under tensile stresses [sigma] = 250 MPa has been found to be optimum for the high-temperature application (up to 550[degrees]C) of the studied alloy. 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subjects Alloys
Analysis
Anisotropy
Annealing
Magnetic fields
Magnetic properties
Specialty metals industry
title Thermal stability of magnetic properties of nanocrystalline [.sub.88][Hf.sub.4][Mo.sub.2][Zr.sub.1][B.sub.4][Cu.sub.1] alloy with induced magnetic anisotropy
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