H. W. Sheng scite author profile

Unlike the well-defined long-range order that characterizes crystalline metals, the atomic arrangements in amorphous alloys remain mysterious at present. Despite intense research activity on metallic glasses and relentless pursuit of their structural description, the details of how the atoms are packed in amorphous metals are generally far less understood than for the case of network-forming glasses. Here we use a combination of state-of-the-art experimental and computational techniques to resolve the atomic-level structure of amorphous alloys. By analysing a range of model binary systems that involve different chemistry and atomic size ratios, we elucidate the different types of short-range order as well as the nature of the medium-range order. Our findings provide a reality check for the atomic structural models proposed over the years, and have implications for understanding the nature, forming ability and properties of metallic glasses.

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Atomic Level Structure in Multicomponent Bulk Metallic Glass

Cheng

2009

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The atomic-level structure of a representative ternary Cu-Zr-Al bulk metallic glass (BMG) has been resolved. Cu- (and Al-) centered icosahedral clusters are identified as the basic local structural motifs. Compared with the Cu-Zr base binary, a small percentage of Al in the ternary BMG leads to dramatically increased population of full icosahedra and their spatial connectivity. The stabilizing effect of Al is not merely topological, but also has its origin in the electronic interactions and bond shortening.

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Deformation Twinning in Nanocrystalline Aluminum

Chen

Hemker

et al. 2003

Science

1,108

461

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We report transmission electron microscope observations that provide evidence of deformation twinning in plastically deformed nanocrystalline aluminum. The presence of these twins is directly related to the nanocrystalline structure, because they are not observed in coarse-grained pure aluminum. We propose a dislocation-based model to explain the preference for deformation twins and stacking faults in nanocrystalline materials. These results underscore a transition from deformation mechanisms controlled by normal slip to those controlled by partial dislocation activity when grain size decreases to tens of nanometers, and they have implications for interpreting the unusual mechanical behavior of nanocrystalline materials.

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Highly optimized embedded-atom-method potentials for fourteen fcc metals

et al. 2011

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Highly optimized embedded-atom-method (EAM) potentials have been developed for 14 face-centered cubic (fcc) elements across the periodic table. The potentials were developed by fitting the potential energy surface (PES) of each element derived from high-precision first-principle calculations. The as-derived potential energy surfaces were shifted and scaled to match experimental reference data. In constructing the PES, a variety of properties of the elements were considered, including lattice dynamics, mechanical properties, thermal behavior, energetics of competing crystal structures, defects, deformation paths, liquid structures, and so forth. For each element, the constructed EAM potentials were tested against the experiment data pertaining to thermal expansion, melting, and liquid dynamics via molecular dynamics (MD) computer simulation. The as-developed potentials demonstrate high fidelity and robustness. Owing to their improved accuracy and wide applicability, the potentials are suitable for highquality atomistic computer simulation of practical applications.2

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H. W. Sheng

Atomic packing and short-to-medium-range order in metallic glasses

Atomic Level Structure in Multicomponent Bulk Metallic Glass

Deformation Twinning in Nanocrystalline Aluminum

Highly optimized embedded-atom-method potentials for fourteen fcc metals

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