Nano-scale grain growth kinetics

Feng Liu; Gencang Yang; Haifeng Wang; Zheng Chen; Yaohe Zhou

doi:10.1016/j.tca.2006.01.028

Nano-scale grain growth kinetics

Feng Liu, Gencang Yang, Haifeng Wang, Zheng Chen, Yaohe Zhou

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

28 Scopus citations

Abstract

An empirical relation among three important properties of grain boundary (GB), i.e. GB free energy, energy change of GB segregation, and GB excess, was shown. Accordingly, GB energy reduces with grain growth. Once GB energy is equal to zero, GBs will be in thermodynamic equilibrium in the presence of solute atoms and, therefore, grain growth stops with saturated GBs. Applying a kinetic model for nano-scale grain growth, some published experimental data were successfully reinterpreted. With progressing grain growth, the activation energy of grain growth increases, in contrast with the reduction of GB energy. In connection with a semi-empirical relation according to the conjecture that GB energy is the difference between those responsible for diffusion in the lattice and the GB itself, proposed by Borisov, a conclusion can be drawn that, for alloy with strong segregation tendency, grain growth is inhibited due to the reduction of GB energy, even to zero.

Original language	English
Pages (from-to)	212-216
Number of pages	5
Journal	Thermochimica Acta
Volume	443
Issue number	2
DOIs	https://doi.org/10.1016/j.tca.2006.01.028
State	Published - 15 Apr 2006

Keywords

Diffusion
Grain boundary
Grain growth
Nano-scale

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10.1016/j.tca.2006.01.028

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title = "Nano-scale grain growth kinetics",

abstract = "An empirical relation among three important properties of grain boundary (GB), i.e. GB free energy, energy change of GB segregation, and GB excess, was shown. Accordingly, GB energy reduces with grain growth. Once GB energy is equal to zero, GBs will be in thermodynamic equilibrium in the presence of solute atoms and, therefore, grain growth stops with saturated GBs. Applying a kinetic model for nano-scale grain growth, some published experimental data were successfully reinterpreted. With progressing grain growth, the activation energy of grain growth increases, in contrast with the reduction of GB energy. In connection with a semi-empirical relation according to the conjecture that GB energy is the difference between those responsible for diffusion in the lattice and the GB itself, proposed by Borisov, a conclusion can be drawn that, for alloy with strong segregation tendency, grain growth is inhibited due to the reduction of GB energy, even to zero.",

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author = "Feng Liu and Gencang Yang and Haifeng Wang and Zheng Chen and Yaohe Zhou",

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T1 - Nano-scale grain growth kinetics

AU - Liu, Feng

AU - Yang, Gencang

AU - Wang, Haifeng

AU - Chen, Zheng

AU - Zhou, Yaohe

PY - 2006/4/15

Y1 - 2006/4/15

N2 - An empirical relation among three important properties of grain boundary (GB), i.e. GB free energy, energy change of GB segregation, and GB excess, was shown. Accordingly, GB energy reduces with grain growth. Once GB energy is equal to zero, GBs will be in thermodynamic equilibrium in the presence of solute atoms and, therefore, grain growth stops with saturated GBs. Applying a kinetic model for nano-scale grain growth, some published experimental data were successfully reinterpreted. With progressing grain growth, the activation energy of grain growth increases, in contrast with the reduction of GB energy. In connection with a semi-empirical relation according to the conjecture that GB energy is the difference between those responsible for diffusion in the lattice and the GB itself, proposed by Borisov, a conclusion can be drawn that, for alloy with strong segregation tendency, grain growth is inhibited due to the reduction of GB energy, even to zero.

AB - An empirical relation among three important properties of grain boundary (GB), i.e. GB free energy, energy change of GB segregation, and GB excess, was shown. Accordingly, GB energy reduces with grain growth. Once GB energy is equal to zero, GBs will be in thermodynamic equilibrium in the presence of solute atoms and, therefore, grain growth stops with saturated GBs. Applying a kinetic model for nano-scale grain growth, some published experimental data were successfully reinterpreted. With progressing grain growth, the activation energy of grain growth increases, in contrast with the reduction of GB energy. In connection with a semi-empirical relation according to the conjecture that GB energy is the difference between those responsible for diffusion in the lattice and the GB itself, proposed by Borisov, a conclusion can be drawn that, for alloy with strong segregation tendency, grain growth is inhibited due to the reduction of GB energy, even to zero.

KW - Diffusion

KW - Grain boundary

KW - Grain growth

KW - Nano-scale

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DO - 10.1016/j.tca.2006.01.028

M3 - 文章

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VL - 443

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JO - Thermochimica Acta

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Nano-scale grain growth kinetics

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