一种新分组团簇动力学模型模拟铝合金中的<strong>Al<sub>3</sub>Sc</strong>析出

doi:10.11900/0412.1961.2020.00289

金属学报

2021, Vol. 57

Issue (6): 822-830 DOI: 10.11900/0412.1961.2020.00289

研究论文

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一种新分组团簇动力学模型模拟铝合金中的Al₃Sc析出

许坤¹, 王海川¹, 孔辉¹, 吴朝阳¹(

), 张战²

^1.安徽工业大学冶金减排与资源综合利用教育部重点实验室马鞍山 243032
^2.武汉科技大学材料与冶金学院武汉 430081

Precipitation Kinetics of Al₃Sc in Aluminum Alloys Modeled with a New Grouping Cluster Dynamics Model

XU Kun¹, WANG Haichuan¹, KONG Hui¹, WU Zhaoyang¹(

), ZHANG Zhan²

^1.Key Laboratory of Metallurgical Emission Reduction & Resources Recyling, Ministry of Education, Anhui University of Technology, Ma'anshan 243032, China
^2.School of Materials and Metallurgy, Wuhan University of Science and Technology, Wuhan 430081, China

引用本文:

许坤, 王海川, 孔辉, 吴朝阳, 张战. 一种新分组团簇动力学模型模拟铝合金中的Al₃Sc析出[J]. 金属学报, 2021, 57(6): 822-830.
Kun XU, Haichuan WANG, Hui KONG, Zhaoyang WU, Zhan ZHANG. Precipitation Kinetics of Al₃Sc in Aluminum Alloys Modeled with a New Grouping Cluster Dynamics Model[J]. Acta Metall Sin, 2021, 57(6): 822-830.

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摘要:

先详细介绍了未分组团簇动力学模型和已有的分组法，然后引入一种基于组内团簇密度对数线性分布的新方法。通过比较未分组和不同分组法的团簇动力学模型模拟300℃时Al-0.18%Sc (原子分数)合金中Al₃Sc的析出动力学的数值解，证实新的分组法能在保持良好整体和局部精度的前提下显著节约计算成本。新分组法的计算结果与等温析出实验测量的析出平均半径和尺寸分布结果能够比较合理地吻合，预期它在大尺度析出模拟时前景良好。

关键词 ：析出动力学, 团簇动力学模型, 粒径分组法, Al-Sc合金, 均质析出

Abstract：

Cluster dynamics is a mesoscopic modeling technique describing the various kinetic stages of homogeneous precipitation by the same set of rate equations. However, when the simulated cluster size continuously increases, it easily causes an enormous computational workload, and the use of a particle-size-grouping method is often necessary to solve this problem. In this study, an ungrouped cluster dynamics model and certain existing grouping methods are reviewed. Next, a new grouping method with an assumed logarithmically-linear distribution of cluster number densities inside each group size is proposed. Comparing the results of all grouped models with the exact solution of the ungrouped model for simulating aluminum-scandium (Al₃Sc) precipitation in the Al-0.18%Sc (atomic fraction) alloy at 300^oC, the new grouping method was able to reduce computational costs considerably keeping enough total and local accuracies. Moreover, the reasonable agreements of the mean radii and size distributions as functions of time between experiments and simulations were obtained, demonstrating the ability of the new grouping method in modeling large-scale precipitation kinetics.

Key words： precipitation kinetics cluster dynamics model particle-size-grouping method Al-Sc alloy homogeneous precipitation

收稿日期: 2020-08-05

ZTFLH:

TG146.2

基金资助:国家自然科学基金项目(U1960109);安徽省留学回国人员创新创业扶持计划重点项目

作者简介: 许坤，男，1978年生，副教授，博士

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https://www.ams.org.cn/CN/10.11900/0412.1961.2020.00289 或 https://www.ams.org.cn/CN/Y2021/V57/I6/822

图1 3种粒径分组法和未分组团簇动力学模型计算的Al3Sc团簇组尺寸分布的比较(a) Kiritani method(b) G-O method(c) new grouping method

表1 析出时间1 × 107 s时对应的不同团簇动力学模型的计算成本的比较

图2 3种粒径分组法和未分组团簇动力学模型计算的Al3Sc未分组团簇尺寸分布的比较(a) Kiritani method(b) G-O method(c) new grouping method

图3 Al-0.18%Sc合金300℃等温析出Al3Sc时的计算结果和测量结果的比较(a) total number density (NP)(b) mean radius (rP)

图4 300℃等温析出时归一化Al3Sc尺寸分布计算结果与实验测量和LSW分布的比较

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