Machine learning accelerated design of non-equiatomic refractory high entropy alloys based on first principles calculation

The properties of High Entropy Alloys (HEAs) strongly depend on the composition and content of elements. However, it was difficult to obtain the optimized element composition through the traditional "trial and error" method. The non-equiatomic HEAs have a large range for composition explor...

Full description

Saved in:
Bibliographic Details
Published in:Vacuum 2023-01, Vol.207, p.111608, Article 111608
Main Authors: Gao, Yu, Bai, Songsong, Chong, Kai, Liu, Chang, Cao, Yingwen, Zou, Yong
Format: Article
Language:English
Subjects:
Elastic properties
Machine learning
Non-equiatomic refractory high entropy alloys
The first-principles calculation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The properties of High Entropy Alloys (HEAs) strongly depend on the composition and content of elements. However, it was difficult to obtain the optimized element composition through the traditional "trial and error" method. The non-equiatomic HEAs have a large range for composition exploration by changing the content of elements, but the current research methods are difficult to analyze comprehensively. In this work, the prediction model with high accuracy is established by mixture design, the first principles calculation and machine learning. The model is used to predict the elastic properties and Poisson's ratio of non-equiatomic Mo–Nb–Ta–Ti–V HEAs, and the prediction results agree well with experimental data. The optimal element composition range of elastic properties and Poisson's ratio could be obtained. The influence of elements on the elastic properties and Poisson's ratio is analyzed through the calculation of features' importance. The results show that the content of Ti has the greatest contribution to the elastic properties and Poisson's ratio of the alloy. This model can not only obtain a large amount of data quickly and accurately but also help us to establish the relationship between element content and mechanical properties of non-equiatomic Mo–Nb–Ta–Ti–V RHEAs and provide theoretical guidance for experiments. [Display omitted] •Refractory high entropy alloys were prepared by arc melting in vacuum.•The first principle calculation data are in good agreement with experimental results.•Prediction of physical properties of high entropy alloys by machine learning.•The optimized range of alloy elements was obtained based on machine learning.
ISSN:0042-207X
1879-2715
DOI:10.1016/j.vacuum.2022.111608