Three-dimensional atomic packing in amorphous solids with liquid-like structure

Liquids and solids are two fundamental states of matter. However, our understanding of their three-dimensional atomic structure is mostly based on physical models. Here we use atomic electron tomography to experimentally determine the three-dimensional atomic positions of monatomic amorphous solids,...

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Veröffentlicht in:	Nature materials 2022-01, Vol.21 (1), p.95-102
Hauptverfasser:	Yuan, Yakun, Kim, Dennis S., Zhou, Jihan, Chang, Dillan J., Zhu, Fan, Nagaoka, Yasutaka, Yang, Yao, Pham, Minh, Osher, Stanley J., Chen, Ou, Ercius, Peter, Schmid, Andreas K., Miao, Jianwei
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Schlagworte:	639/301/1023/218 639/301/357/354 639/301/930/328/2082 639/766/119/1002 Amorphous materials Amorphous structure Atomic structure Biomaterials Chemistry and Materials Science Condensed Matter Physics Crystal structure Crystallinity Glasses Icosahedrons Liquids MATERIALS SCIENCE Molecular dynamics Nanoparticles Nanotechnology Networks Optical and Electronic Materials Solids Structure of solids and liquids Thin films Tomography Transmission electron microscopy
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creator	Yuan, Yakun Kim, Dennis S. Zhou, Jihan Chang, Dillan J. Zhu, Fan Nagaoka, Yasutaka Yang, Yao Pham, Minh Osher, Stanley J. Chen, Ou Ercius, Peter Schmid, Andreas K. Miao, Jianwei
description	Liquids and solids are two fundamental states of matter. However, our understanding of their three-dimensional atomic structure is mostly based on physical models. Here we use atomic electron tomography to experimentally determine the three-dimensional atomic positions of monatomic amorphous solids, namely a Ta thin film and two Pd nanoparticles. We observe that pentagonal bipyramids are the most abundant atomic motifs in these amorphous materials. Instead of forming icosahedra, the majority of pentagonal bipyramids arrange into pentagonal bipyramid networks with medium-range order. Molecular dynamics simulations further reveal that pentagonal bipyramid networks are prevalent in monatomic metallic liquids, which rapidly grow in size and form more icosahedra during the quench from the liquid to the glass state. These results expand our understanding of the atomic structures of amorphous solids and will encourage future studies on amorphous–crystalline phase and glass transitions in non-crystalline materials with three-dimensional atomic resolution. Atomic electron tomography is used to determine the three-dimensional atomic structure of monatomic amorphous solids with liquid-like structure, which is characterized by the existence of pentagonal bipyramid networks with medium-range order.
doi_str_mv	10.1038/s41563-021-01114-z
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subjects	639/301/1023/218 639/301/357/354 639/301/930/328/2082 639/766/119/1002 Amorphous materials Amorphous structure Atomic structure Biomaterials Chemistry and Materials Science Condensed Matter Physics Crystal structure Crystallinity Glasses Icosahedrons Liquids MATERIALS SCIENCE Molecular dynamics Nanoparticles Nanotechnology Networks Optical and Electronic Materials Solids Structure of solids and liquids Thin films Tomography Transmission electron microscopy
title	Three-dimensional atomic packing in amorphous solids with liquid-like structure
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