Lingjie Luo scite author profile

2014) 24 electron cluster formulas as the 'molecular' units of ideal metallic glasses, Philosophical Magazine, 94:22, 2520-2540, It is known that ideal metallic glasses fully complying with the Hume-Rothery stabilization mechanism can be expressed by a universal cluster formula of the form [cluster](glue atom) 1 or 3 . In the present work, it is shown, after a reexamination of the cluster-resonance model, that the number of electrons per unit cluster formula, e/u, is universally 24. The cluster formulas are then the atomic as well as the electronic structural units, mimicking the 'molecular' formulas for chemical substances. The origin of different electron number per atom ratios e/a is related to the total number of atoms Z in unit cluster formula, e/a = 24/Z. The 24 electron formulas are well confirmed in typical binary and ternary bulk metallic glasses.

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Composition formulas of binary eutectics

Dong

Chen

et al. 2015

Sci Rep

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The present paper addresses the long-standing composition puzzle of eutectic points by introducing a new structural tool for the description of short-range-order structural unit, the cluster-plus-glue-atom model. In this model, any structure is dissociated into a 1st-neighbor cluster and a few glue atoms between the clusters, expressed by a cluster formula [cluster]gluex. This model is applied here to establish the structural model for eutectic liquids, assuming that a eutectic liquid consist of two subunits issued from the relevant eutectic phases, each being expressed by the cluster formula for ideal metallic glasses, i.e., [cluster](glue atom)1 or 3. A structural unit is then composed of two clusters from the relevant eutectic phases plus 2, 4, or 6 glue atoms. Such a dual cluster formulism is well validated in all boron-containing (except those located by the extreme phase diagram ends) and in some commonly-encountered binary eutectics, within accuracies below 1 at.%. The dual cluster formulas vary extensively and are rarely identical even for eutectics of close compositions. They are generally formed with two distinctly different cluster types, with special cluster matching rules such as cuboctahedron plus capped trigonal prism and rhombidodecahedron plus octahedral antiprism.

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Hardness of Al-based quasicrystals evaluated via cluster-plus-glue-atom model

Chen

Luo

Qiang

et al. 2014

Philosophical Magazine

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Packing efficiency of coordination polyhedra

Luo

Wang

et al. 2010

Philosophical Magazine

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Comment on “Comparative analysis of glass-formation in binary, ternary, and multicomponent alloys” [J. Appl. Phys. 108, 103511 (2010)]

Luo

Dong

2013

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Lingjie Luo

24 electron cluster formulas as the ‘molecular’ units of ideal metallic glasses

Composition formulas of binary eutectics

Hardness of Al-based quasicrystals evaluated via cluster-plus-glue-atom model

Packing efficiency of coordination polyhedra

Comment on “Comparative analysis of glass-formation in binary, ternary, and multicomponent alloys” [J. Appl. Phys. 108, 103511 (2010)]

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