Abstract
With the discovery of bulk metallic glasses (BMGs), there has been considerable interest in understanding their mechanical behavior. In spite of these previous observations on the relation between plastic deformation of metallic glasses and their diffusion behavior, a detailed understanding on the diffusion of BMGs is still unexplored. We evaluated the contribution of deformation-induced structural transformations (elastic, anelastic, viscoplastic or viscoelastic responsive and plastic strain) on the diffusion of Zr-based bulk metallic glasses in as-cast, elastostatically stressed and plastically deformed states. Experimental investigations of the diffusion process and the elemental distributions in the glassy alloy were performed following plastic deformation by multiple cold rolling and elastostatic cyclic compression, respectively. We compared the vacancy model and the transition state model to verify the diffusion mechanism in the deformed bulk metallic glass. The diffusion of tracer atoms, i.e., Fe, in the bulk metallic glass is affected by viscoelastic responsive strain governing the transition-state model. In contrast, the diffusion of constituent atoms, i.e., Ti, Zr, in the bulk metallic glass is dominantly affected by plastic strain governing the vacancy model. The results reveal that the diffusion behavior of bulk glassy alloys can be changed by variation of the constituent elements and applying different strain modes upon deformation.
Highlights
With the discovery of bulk metallic glasses (BMGs), there has been considerable interest in understanding their mechanical behavior
differential scanning calorimeter (DSC) traces obtained for as-cast Zr55Ti5Al10Cu20Ni10 BMG, elastostatically loaded samples and cold-rolled, diffusion annealed specimens. (Inset) Enlarged view of the rectangular regions near to the glass transition temperature (Tg) showing the exothermic heat released as a result of the reduction of disorder associated with structural relaxation during heating
The X-ray diffraction (XRD) patterns of the as-cast, plastically cold-rolled and elastically loaded Zr55Ti5Al10Cu20Ni10 BMGs in Fig. 1(a) show the typical broad diffraction maxima characteristic for amorphous materials and no distinct crystalline peaks are detected within the sensitivity limits of XRD
Summary
With the discovery of bulk metallic glasses (BMGs), there has been considerable interest in understanding their mechanical behavior.
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