Predicting the Hardness of Al-Sc-X Alloys with Machine Learning Models, Explainable Artificial Intelligence Analysis and Inverse Design

IF 1.1 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Korean Journal of Metals and Materials Pub Date : 2023-11-05 DOI:10.3365/kjmm.2023.61.11.874

Jiwon Park, Su-Hyeon Kim, Jisu Kim, Byung-joo Kim, Hyun-seok Cheon, Chang-Seok Oh

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引用次数: 0

Abstract

In this study, the Vickers hardness of precipitation-strengthened Al-Sc-X (X = Zr, Si, and Fe) alloys were predicted using machine learning models, depending on the alloys’ compositions, solid-solution treatment and aging conditions. The data used for machine learning were collected from the literature. Among the models, tree-based ensemble models such as extreme gradient boosting and random forest performed well. Then the feature impact on the model output was analyzed with SHarpely Additive eXplanation (SHAP). Based on the SHAP analysis and prior domain knowledge, the process conditions were restricted to narrow down the inverse design search space. Candidate alloys suggested by the optimization using a genetic algorithm showed improved hardness values. The hardness prediction model and the inverse designsuggested candidates were then experimentally validated. The accuracy of the hardness prediction model was 0.994, when the predicted hardness was 85.4 Hv, and the experimentally measured hardness was 84.9 Hv. A specimen whose composition was close to the inverse-designed alloy was cast and heat treated according to the suggested conditions. The inverse design showed an accuracy of 0.965. Exploring the entire combination of possible feature space requires vast effort and time. An efficient search for materials with improved properties can be achieved using an appropriate configuration of well-performing machine learning models and explainable AI techniques guided by domain knowledge.

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利用机器学习模型、可解释人工智能分析和逆向设计预测Al-Sc-X合金硬度

在这项研究中，根据合金的成分、固溶处理和时效条件，使用机器学习模型预测了析出强化Al-Sc-X (X = Zr、Si和Fe)合金的维氏硬度。用于机器学习的数据是从文献中收集的。其中，基于树的集成模型(如极端梯度增强和随机森林)表现较好。然后利用夏普加性解释(SHarpely Additive eXplanation, SHAP)分析特征对模型输出的影响。基于SHAP分析和先验领域知识，限制工艺条件，缩小逆向设计搜索空间。采用遗传算法优化后的候选合金硬度值有所提高。并对硬度预测模型和推荐的候选材料进行了实验验证。当预测硬度为85.4 Hv时，硬度预测模型的精度为0.994，实验测量硬度为84.9 Hv。将成分接近反设计合金的试样按建议条件进行铸造和热处理。反设计精度为0.965。探索可能的特征空间的整个组合需要大量的精力和时间。使用性能良好的机器学习模型和由领域知识指导的可解释的人工智能技术的适当配置，可以实现对具有改进性能的材料的有效搜索。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Korean Journal of Metals and Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-METALLURGY & METALLURGICAL ENGINEERING

CiteScore

1.80

自引率

58.30%

发文量

100

审稿时长

4-8 weeks

期刊介绍： The Korean Journal of Metals and Materials is a representative Korean-language journal of the Korean Institute of Metals and Materials (KIM); it publishes domestic and foreign academic papers related to metals and materials, in abroad range of fields from metals and materials to nano-materials, biomaterials, functional materials, energy materials, and new materials, and its official ISO designation is Korean J. Met. Mater.