Journal ArticleDOI
Origin of low coercivity of (Fe0.75B0.15Si0.10)100−xNbx (x=1–4) glassy alloys
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In this paper, the authors investigated the magnetization process of the melt-spun (Fe0.75B0.15Si0.10) 100−xNbx (x=1-4) glassy alloys to clarify the origin of low coercivity.Abstract:
The density and the magnetization process of the melt-spun (Fe0.75B0.15Si0.10)100−xNbx (x=1–4) glassy alloys have been investigated to clarify the origin of low coercivity (Hc). Both Hc and the difference of the densities between the crystalline and glassy phases, which corresponds to the free volume in the glassy phase, decrease with increasing Nb content. An analysis of the magnetization process based on the law of approach to ferromagnetic saturation reveals that quasidislocation dipole (QDD)-type defects are the main sources of elastic stress. The results also suggest that the pinning force for magnetic domain walls generated by one QDD-type defect is independent of the Nb content, but the number density of QDDs decreases with increasing the Nb content. Therefore, it concluded that the origin of low Hc of the glassy alloys is the low number density of QDDs which corresponds to the low number density of the domain-wall pinning sites.read more
Citations
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Composition design of high B-s Fe-based amorphous alloys with good amorphous-forming ability
TL;DR: In this article, the composition design rules for high B s amorphous alloys are introduced from the binary phase diagram, atomic size and the effects of amorphizing forming elements on magnetic performance and ribbon manufacturability.
Journal ArticleDOI
FeSiBP bulk metallic glasses with high magnetization and excellent magnetic softness
TL;DR: In this article, the authors presented a novel Fe-rich FeSiBP BMG with high saturation magnetization (Js) of 1.51 T comparable to the ordinary Fe-Si-B amorphous alloy now in practical use.
Journal ArticleDOI
FeSiBP metallic glasses with high glass-forming ability and excellent magnetic properties
TL;DR: In this paper, a Fe76Si9B10P5 (atomic percent) alloy with high saturation magnetization (J) and high glass-forming ability (GFA) was developed.
Journal ArticleDOI
Fe-based amorphous alloys for wide ribbon production with high Bs and outstanding amorphous forming ability
TL;DR: FeCBSiP alloys with high B s and amorphous-forming ability as well as good soft-magnetic properties were developed via component design and composition adjustment as discussed by the authors.
Journal ArticleDOI
FeSiBP Bulk Metallic Glasses with Unusual Combination of High Magnetization and High Glass-Forming Ability
TL;DR: In this paper, a novel Fe76Si9B10P5 (at%) bulk metallic glass with unusual combination of high saturation magnetization (Js) of 1.51 T due to high Fe content and high GFA leading to a glassy rod with a diameter of 2.5 mm despite not containing any glass-forming metal elements.
References
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Journal ArticleDOI
Fe-Based Ferromagnetic Glassy Alloys with Wide Supercooled Liquid Region
Akihisa Inoue,Jin Seon Gook +1 more
TL;DR: In this paper, a multicomponent Fe 72 Al 5 Ga 2 P 11 C 6 B 4 alloy was found to form a glassy phase with a wide supercooled liquid region before crystallization and of ferromagnetism at room temperature.
Journal ArticleDOI
Theory of the coercive field in amorphous ferromagnetic alloys
TL;DR: The coercive field of amorphous ferromagnetic alloys is determined by defect structures, surface irregularities, relaxation phenomena and intrinsic fluctuations of the material properties within the framework of micromagnetism.
Journal ArticleDOI
Soft magnetic bulk glassy Fe-B-Si-Nb alloys with high saturation magnetization above 1.5 T
Akihisa Inoue,Baolong Shen +1 more
TL;DR: In this article, a new Fe-based bulk glassy alloys were synthesized in the (Fe 0.75 B 0.15 Si 0.10 ) 100-x Nb x system by copper mold casting.
Journal ArticleDOI
Micromagnetism and microstructure of amorphous alloys (invited)
TL;DR: A detailed analysis of experimental results on the basis of the theory of micromagnetism for inhomogeneous systems shows clearly that the ferromagnetic phase transition is mainly influenced by intrinsic exchange fluctuations whereas the characteristic properties of the magnetization curve are governed predominantely by defect structures as mentioned in this paper.
Journal ArticleDOI
Micromagnetism in Amorphous Alloys
TL;DR: In this article, Brown's micromagnetic equations are derived for the case of dipolar and magnetocrystalline fluctuations in amorphous ferromagnetic alloys and the influence of these fluctuations and the effects of internal stresses of so-called quasi-dislocation dipoles on the law of approach to saturation is discussed in detail.