Influence of thermally induced structural transformations on hardness in Fe sub(89.8)Ni sub(1.5)Si sub(5.2)B sub(3)C sub(0.5) amorphous alloy

Influence of thermally induced structural transformations on hardness in Fe sub(89.8)Ni sub(1.5)Si sub(5.2)B sub(3)C sub(0.5) amorphous alloy

Effect of heat treatment on mechanical behavior of Fe sub(89.8)Ni sub(1.5)Si sub(5.2)B sub(3)C sub(0.5) amorphous alloy was investigated by measuring microhardness. It was shown that the as-prepared amorphous alloy has an unexpectedly high microhardness. This can be attributed not only to boron disp...

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Bibliographic Details
Published in:Journal of alloys and compounds Vol. 509; no. 33; pp. 8350 - 8355
Main Authors: Minic, D M, Blagojevic, V, Minic, D G, Gavrilovic, A, Rafailovic, L
Format: Journal Article
Language:English
Published: 18-08-2011
Subjects:
Alloys
Amorphous alloys
Crystal structure
Dispersion
Heat treatment
Metallic glasses
Microhardness
Nanostructure
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Summary:Effect of heat treatment on mechanical behavior of Fe sub(89.8)Ni sub(1.5)Si sub(5.2)B sub(3)C sub(0.5) amorphous alloy was investigated by measuring microhardness. It was shown that the as-prepared amorphous alloy has an unexpectedly high microhardness. This can be attributed not only to boron dispersed in the alloy, but also to the structure which exhibits aspects of a nanocomposite of nanoparticles dispersed in an amorphous matrix. As the alloy crystallizes at temperatures above 540 degree C, microhardness decreases continuously as a function of heating temperature. This is attributed to separation of boron out of the amorphous matrix into nanocrystals of Fe sub(2)B phase. Further decrease in microhardness is attributed to crystallite growth with the accompanying change in the dominant nature of the interfaces from amorphous/crystal to crystal/crystal, and creation of a porous structure. When the crystallization is complete, the alloy exhibits microhardness close to that of a hypothetical mixture of alpha -Fe and Fe sub(2)B phases of the same composition.
Bibliography:ObjectType-Article-2
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ISSN:0925-8388
DOI:10.1016/j.jallcom.2011.03.011