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Plastic deformation effect on formation of nanocrystals in Co-based amorphous alloys
Russian version
Abrosimova G.E.1, Jimenez Remache D.I.1, Chirkova V.V.1, Aronin A.S.1
1Institute of Solid State Physics, Russian Academy of Sciences, Chernogolovka, Moscow region, Russia
Email: gea@issp.ac.ru
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The impact of deformation on crystallization of Co67Si12B9Fe7Nb5 amorphous alloy has been studied by methods of X-ray, scanning and transmission electron microscopy. It was found that deformation leads to the formation of a heterogeneous amorphous structure consisting of shear bands (areas of reduced density) and a non-deformed amorphous matrix surrounding them. The average change in the distance between the atoms in a deformed amorphous alloy compared to the non-deformed one is 0.12 %. Because of the formed reduced density regions the crystallization processes is accelerated and a material with a higher proportion of the crystalline phase may be obtained. The formation of nanocrystals with a body-centered cubic (BCC) lattice in an amorphous cobalt alloy is discussed under the assumption that a crystal nucleation occurs in the ordered regions where the short-range order corresponds to that of the BCC-phase being formed. Keywords: amorphous phase, shear bands, nanocrystallization, transmission electron microscopy, X-ray analysis.
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