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Random forest incorporating ab-initio calculations for corrosion rate prediction with small sample Al alloys data

Journal Article (2022)
Author(s)

Y. Ji (University of Science and Technology Beijing, TU Delft - Materials Science and Engineering)

Ni Li (University of Science and Technology Beijing)

Zhanming Cheng (University of Science and Technology Beijing)

Xiaoqian Fu (University of Science and Technology Beijing)

Xiaoguang Sun (CRRC Qingdao Sifang Co. Ltd)

Thee Chowwanonthapunya (Kasetsart University)

Dawei Zhang (University of Science and Technology Beijing)

Jingli Ren (Zhengzhou University)

Poulumi Dey (TU Delft - Team Poulumi Dey)

Chaofang Dong (University of Science and Technology Beijing)

More authors (External organisation)

Department
Materials Science and Engineering
Copyright
© 2022 Y. Ji, Ni Li, Zhanming Cheng, Xiaoqian Fu, Xiaoguang Sun, Thee Chowwanonthapunya, Dawei Zhang, Jingli Ren, P. Dey, Chaofang Dong, More Authors
DOI related publication
https://doi.org/10.1038/s41529-022-00295-5
More Info
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Publication Year
2022
Language
English
Copyright
© 2022 Y. Ji, Ni Li, Zhanming Cheng, Xiaoqian Fu, Xiaoguang Sun, Thee Chowwanonthapunya, Dawei Zhang, Jingli Ren, P. Dey, Chaofang Dong, More Authors
Department
Materials Science and Engineering
Issue number
1
Volume number
6
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Abstract

Corrosion jeopardizes the materials longevity and engineering safety, hence the corrosion rate needs to be forecasted so as to better guide materials selection. Although field exposure experiments are dependable, the prohibitive cost and their time-consuming nature make it difficult to obtain large dataset for machine learning. Here, we propose a strategy Integrating Ab-initio Calculations with Random Forest (IACRF) to optimize the model, thereby estimating the corrosion rate of Al alloys in diverse environments. Based on the thermodynamic assessment of the secondary phases, the ab-initio calculation quantities, especially the work function, significantly improved the prediction accuracy with respect to small-sample Al alloys corrosion dataset. To build a better generic prediction model, the most accessible and effective features are identified to train IACRF. Finally, the independent field exposure experiments in Southeast Asia have proven the generalization ability of IACRF in which the average prediction accuracy is improved up to 91%.