Structural mechanisms of the high glass-forming ability in CuZrTiPd metallic glass

The issue, high glass-forming abilities (GFAs) in solute-absent multicomponent metallic glasses (MGs), has been investigated by systematic experimental measurements coupled with theoretical calculations in the Cu 34 Zr 14 Ti 36 Pd 16 quaternary alloy. It is found that the synergetic contribution of...

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Veröffentlicht in:	Journal of materials science 2019-11, Vol.54 (22), p.14209-14217
Hauptverfasser:	Li, Ming-Fei, Liao, Bing, Wang, Yin-Gang, Yang, Liang
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Sprache:	eng
Schlagworte:	Alloy development Amorphous materials Atoms Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Clusters Crystallography and Scattering Methods Glass Glass formation Icosahedral phase Materials Science Metallic glasses Metals & Corrosion Optimization Organic chemistry Palladium Polymer Sciences Quaternary alloys Solid Mechanics Titanium Zirconium
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creator	Li, Ming-Fei Liao, Bing Wang, Yin-Gang Yang, Liang
description	The issue, high glass-forming abilities (GFAs) in solute-absent multicomponent metallic glasses (MGs), has been investigated by systematic experimental measurements coupled with theoretical calculations in the Cu 34 Zr 14 Ti 36 Pd 16 quaternary alloy. It is found that the synergetic contribution of some atomic- and cluster-level structural features leads to the high GFA in this quaternary composition. At the atomic scale, Pd and Ti addition decreases the size gaps between Cu and Zr atoms, and increases the atomic packing efficiency; at the cluster scale, there are more icosahedral or icosahedral-like local structures, and the cluster regularity is enhanced because of the optimization of both topological and chemical distributions in clusters. The present work provides an in-depth understanding of GFAs in multicomponent alloys, and will shed light on the development of more MGs with high GFAs.
doi_str_mv	10.1007/s10853-019-03890-1
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subjects	Alloy development Amorphous materials Atoms Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Clusters Crystallography and Scattering Methods Glass Glass formation Icosahedral phase Materials Science Metallic glasses Metals & Corrosion Optimization Organic chemistry Palladium Polymer Sciences Quaternary alloys Solid Mechanics Titanium Zirconium
title	Structural mechanisms of the high glass-forming ability in CuZrTiPd metallic glass
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