Shuo Dang scite author profile

A deep understanding of the coarsening kinetics of nanoparticles on substrates is of great fundamental and critical importance for controlling the material properties. However, in situ observation of the coarsening process at the atomic scale is still very difficult, and the influence of the substrate on coarsening kinetics remains largely unknown. In this work, by using an atomic-scale phase-field crystal model, we investigated the coarsening kinetics of nanoparticles on fcc (111) surface substrates. The results showed that the number of steps and local curvature near the particle surface increase with the pinning potential of substrates, leading to an increase in the coarsening rate. By examining the particles' atomic configurations during coarsening, we find that the particles rotate with time and the speed of rotation is influenced by the particle radius and the initial misorientations. In addition, we observe inverse coarsening behavior in the initial state of coarsening. We find that the particles with smaller radii or lower misorientations rotate faster to the stable state and then grow continuously at the expense of the surrounding particles. Our simulations in this work provide dynamic imaging of the coarsening process of nanoparticles on the substrates and show that crystalline characteristics or atomic scale nature have significant influences on the coarsening kinetics.

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Design and Implementation of Supply Chain Integrated System Based on Internet of Things

Chu

Chen

Dang

2013

AMM

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In recent years, the technology of the Internet of Things has attracted highly attention of academia, enterprise and news media. This paper made a brief introduction of the connotation and application prospect of Internet of Things, analysed the supply chain management problems in Chinese enterprises, stated the effects of Internet of Things on supply chain management. We designed the supply chain architecture based on EPC Net work, proposed the supply chain integrated system application model based on Internet of Things, designed and implemented the drug supply chain logistics business process system based on Internet of Things.

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A microscopic spatially confined strategy to realize completely reversible self-healing lattice restoration of MoS₂ for ultrastable reversible sodium-ion storage

Wei¹,

Tian²,

Lin

et al. 2021

New J. Chem.

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Shuo Dang

Evaluation framework and verification for sustainable container management as reusable packaging

Coarsening Process of Nanoparticles on Substrates by the Phase-Field Crystal Model

Design and Implementation of Supply Chain Integrated System Based on Internet of Things

A microscopic spatially confined strategy to realize completely reversible self-healing lattice restoration of MoS₂ for ultrastable reversible sodium-ion storage

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Shuo Dang

Evaluation framework and verification for sustainable container management as reusable packaging

Coarsening Process of Nanoparticles on Substrates by the Phase-Field Crystal Model

Design and Implementation of Supply Chain Integrated System Based on Internet of Things

A microscopic spatially confined strategy to realize completely reversible self-healing lattice restoration of MoS2 for ultrastable reversible sodium-ion storage

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Product

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A microscopic spatially confined strategy to realize completely reversible self-healing lattice restoration of MoS₂ for ultrastable reversible sodium-ion storage