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A comparative study of Sm networks in Al-10 at.%Sm glass and associated crystalline phases

TitleA comparative study of Sm networks in Al-10 at.%Sm glass and associated crystalline phases
Publication TypeJournal Article
Year of Publication2018
AuthorsLv, XB, Ye, Z, Sun, Y, Zhang, F, Yang, L, Lin, ZJ, Wang, CZ, Ho, KM
JournalPhilosophical Magazine Letters
Volume98
Pagination27-37
Type of ArticleArticle
ISBN Number0950-0839
Accession NumberWOS:000434666900004
Keywordsal, Al-Sm system, alloy, amorphous, atomic packing, glassy and crystalline states, liquid, liquids, Materials Science, Medium-range order, metallic glasses, Metallurgical Engineering, molecular dynamics simulations, order, physics
Abstract

The Al-Sm system is selected as a model system to study the transition process from liquid and amorphous to crystalline states. In recent work, we have shown that, in addition to long-range translational periodicity, crystal structures display well-defined short-range local atomic packing motifs that transcends liquid, amorphous and crystalline states. In this paper, we investigate the longer range spatial packing of these short-range motifs by studying the interconnections of Sm-Sm networks in different amorphous and crystalline samples obtained from molecular dynamics simulations. In our analysis, we concentrate on Sm-Sm distances in the range similar to 5.0-7.2 angstrom, corresponding to Sm atoms in the second and third shells of Sm-centred clusters. We discover a number of empirical rules characterising the evolution of Sm networks from the liquid and amorphous states to associated metastable crystalline phases experimentally observed in the initial stages of devitrification of different amorphous samples. As direct simulation of glass formation is difficult because of the vast difference between experimental quench rates and what is achievable on the computer, we hope these rules will be helpful in building a better picture of structural evolution during glass formation as well as a more detailed description of phase selection and growth during devitrification.

DOI10.1080/09500839.2018.1447157
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Structures and Dynamics

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Exploratory Theory