Anomalous packing state in Ce-Ga-Cu bulk metallic glasses

Formation mechanism of bulk metallic glasses (BMGs) with high glass-forming ability (GFA) has been a long-standing subject in the field of solid state physics. To highlight the GFA-associated local atomic structure, element-specific positron annihilation spectroscopy was conducted for recently disco...

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Published inIntermetallics Vol. 84; pp. 25 - 29
Main Authors Zhao, Y., Li, D.D., Qu, B.Y., Zhou, R.L., Zhang, B., Sato, K.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.05.2017
Subjects
Bulk metallic glasses
Glass-forming ability
Positron annihilation
Glass-forming ability
Bulk metallic glasses
Positron annihilation
Online AccessGet full text
ISSN0966-9795
DOI10.1016/j.intermet.2016.12.017

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Abstract Formation mechanism of bulk metallic glasses (BMGs) with high glass-forming ability (GFA) has been a long-standing subject in the field of solid state physics. To highlight the GFA-associated local atomic structure, element-specific positron annihilation spectroscopy was conducted for recently discovered ternary Ce70GaxCu30-x (x = 6–13; at.%) BMGs. We succeeded in identifying the packing structure under the condition of ambient pressure, in which Ce atoms are concentrated more than that in Ce crystal. This anomalous glassy state is most efficiently formed at the Ga concentration of ∼10%, where the best glass-forming ability (GFA) is experimentally observed. First-principles computer simulation results suggest that this anomalous packing structure is associated with Ce-4f electron delocalization in the Ce-Ga-Cu BMGs. The findings provide unambiguous evidence for the relationship between the packing-efficient local structure and the GFA. •Positron annihilation revealed an anomalous packing state in CeGaCu bulk metallic glasses.•This anomalous glassy state is most efficiently formed at the best glass forming composition macroscopically observable.•The findings indicate that the locally-concentrated atomic structure is crucial for formation of bulk metallic glasses.
AbstractList Formation mechanism of bulk metallic glasses (BMGs) with high glass-forming ability (GFA) has been a long-standing subject in the field of solid state physics. To highlight the GFA-associated local atomic structure, element-specific positron annihilation spectroscopy was conducted for recently discovered ternary Ce70GaxCu30-x (x = 6–13; at.%) BMGs. We succeeded in identifying the packing structure under the condition of ambient pressure, in which Ce atoms are concentrated more than that in Ce crystal. This anomalous glassy state is most efficiently formed at the Ga concentration of ∼10%, where the best glass-forming ability (GFA) is experimentally observed. First-principles computer simulation results suggest that this anomalous packing structure is associated with Ce-4f electron delocalization in the Ce-Ga-Cu BMGs. The findings provide unambiguous evidence for the relationship between the packing-efficient local structure and the GFA. •Positron annihilation revealed an anomalous packing state in CeGaCu bulk metallic glasses.•This anomalous glassy state is most efficiently formed at the best glass forming composition macroscopically observable.•The findings indicate that the locally-concentrated atomic structure is crucial for formation of bulk metallic glasses.
Author Sato, K.
Li, D.D.
Zhao, Y.
Qu, B.Y.
Zhang, B.
Zhou, R.L.
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Bulk metallic glasses
Positron annihilation
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Snippet Formation mechanism of bulk metallic glasses (BMGs) with high glass-forming ability (GFA) has been a long-standing subject in the field of solid state physics....
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SubjectTerms Bulk metallic glasses
Glass-forming ability
Positron annihilation
Title Anomalous packing state in Ce-Ga-Cu bulk metallic glasses
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