Thermal and Magnetic Properties of Bulk Fe-Based Glassy Alloys Prepared by Copper Mold Casting
TLDR
In this article, a copper mold casting method was used to construct a bulk glassy alloys with diameters of 0.5 and 1.0 mm, and the results showed that the maximum thickness for glass formation is about 10 times larger than the largest thickness for Fe-based alloys reported up to date.Abstract:
Bulk glassy Fe 73 Al 5 Ga 2 P 11 C 5 B 4 alloys in cylindrical form with diameters of 0.5 and 1.0 mm were found to form by a copper mold casting method. The further increase in diameter causes the formation of coexistent glassy, Fe 3 (B, C), Fe 2 B and Fe 3 P phases for the 1.5 mm ? sample and coexistent Fe 3 (B, C), Fe 2 B and Fe 3 P phases for the 2.0 mm ? sample. It is to be noticed that the maximum thickness for glass formation is about 10 times larger than the largest thickness for Fe-based glassy alloys reported up to date. The glass transition temperature (T g ), crystallization temperature (T x ) and heat of crystallization of the 1.0 mm ? glassy alloy are 732 K, 785 K and 3.76 kJ/mol, respectively. No appreciable difference in the thermal stability and magnetic properties is seen between the bulk glassy alloys and the melt-spun ribbon. The 1.0 mm ? glassy alloy has ferromagnetism with a Curie temperature of 606 K and exhibits 1.26 T for saturation magnetization (B s ), 82 A/m for coercivity (H c ) and 0.38 for the ratio of residual magnetization to B s at room temperature. The large ΔT x ( = T x - T g ) and large glass-forming ability can be obtained for the Fe-based alloy containing simultaneously the five solute elements. The effectiveness of the multiplication is presumably due to the combination of the following three effects ; (1) the suppression of crystalline nuclei due to the increase in dense random packing density for the glassy structure containing P, C and B with significantly different atomic sizes, (2) the difficulty of atomic rearrangements for the precipitation of the Fe-metalloid compounds caused by the generation of Al-metalloid pairs with strongly attractive bonding nature, and (3) the decrease in the preferential precipitation tendency of Fe-B and Fe-C compounds by the dissolution of Ga which is immiscible to B and C and soluble to Fe.read more
Citations
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Amorphous and nanocrystalline materials for applications as soft magnets
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Amorphous, nanoquasicrystalline and nanocrystalline alloys in Al-based systems
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Bulk Metallic Glasses
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Iron-based bulk metallic glasses
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References
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Journal ArticleDOI
A highly processable metallic glass: Zr41.2Ti13.8Cu12.5Ni10.0Be22.5
Atakan Peker,William L. Johnson +1 more
TL;DR: In this article, the properties of a new family of metallic alloys which exhibit excellent glass forming ability are reported, where the critical cooling rate to retain the glassy phase is of the order of 10 K/s or less.
Journal ArticleDOI
Glass-forming ability of alloys
TL;DR: In this article, it is assumed that the large glass-forming ability for these alloys is due to a combined effect of the difficulty of long-range atomic redistribution required for the precipitation of the compounds, the rapid increase of viscosity with decreasing temperature and the large liquidus-solidus interfacial energy which originates from the optimally bonding and packing states resulting from large negative heat of mixing and large atomic size ratios.
Journal ArticleDOI
New Amorphous Mg-Ce-Ni Alloys with High Strength and Good Ductility
TL;DR: In this paper, a new Mg-based amorphous alloys with high strength and good ductility were produced in the MgCe-Ni system by melt spinning, and the tensile fracture strength and Vickers hardness reached 750 MPa and 199 DPN for Mg80Ce10Ni10.
Journal ArticleDOI
Ti-based amorphous alloys with a wide supercooled liquid region
TL;DR: The largest temperature interval of the supercooled liquid region ( ΔT x ) is as large as 90 K for Ti 50 Cu 25 Ni 20 Co 5, and there is a tendency for ΔTx to increase with an increase in storage modulus and with a decrease in loss modulus as mentioned in this paper.