Discovery of marageing steels: machine learning vs. physical metallurgical modelling

doi:10.1016/j.jmst.2021.02.017

Abstract

Abstract:

Physical metallurgical (PM) and data-driven approaches can be independently applied to alloy design. Steel technology is a field of physical metallurgy around which some of the most comprehensive understanding has been developed, with vast models on the relationship between composition, processing, microstructure and properties. They have been applied to the design of new steel alloys in the pursuit of grades of improved properties. With the advent of rapid computing and low-cost data storage, a wealth of data has become available to a suite of modelling techniques referred to as machine learning (ML). ML is being emergingly applied in materials discovery while it requires data mining with its adoption being limited by insufficient high-quality datasets, often leading to unrealistic materials design predictions outside the boundaries of the intended properties. It is therefore required to appraise the strength and weaknesses of PM and ML approach, to assess the real design power of each towards designing novel steel grades. This work incorporates models and datasets from well-established literature on marageing steels. Combining genetic algorithm (GA) with PM models to optimise the parameters adopted for each dataset to maximise the prediction accuracy of PM models, and the results were compared with ML models. The results indicate that PM approaches provide a clearer picture of the overall composition-microstructure-properties relationship but are highly sensitive to the alloy system and hence lack on exploration ability of new domains. ML conversely provides little explicit physical insight whilst yielding a stronger prediction accuracy for large-scale data. Hybrid PM/ML approaches provide solutions maximising accuracy, while leading to a clearer physical picture and the desired properties.

Key words: Machine learning, Physical metallurgy, Small sample problem, Marageing steel

Chunguang Shen, Chenchong Wang, Pedro E.J.Rivera-Díaz-del-Castillo, Dake Xu, Qian Zhang, Chi Zhang, Wei Xu. Discovery of marageing steels: machine learning vs. physical metallurgical modelling[J]. J. Mater. Sci. Technol., 2021, 87: 258-268.

Figures/Tables 10

Table 1 The inputs (compositions and ageing condition) and output (hardness, Hv) associated to each dataset. Tage and tage represent ageing temperature and ageing time, respectively.

		C	Cr	Ni	Mo	Al	Mn	Cu	V	Ti	Co	T_age	t_age	Hv
D1	Min	0.002	11.90	1.50	2.0	—	—	—	—	0	11.4	300	3.16	264
	Max	0.09	15.0	6.0	5.3					0.2	20.0	600	4.00	510
	Mean	0.03	12.6	4.4	4.4					0.1	13.0	498	3.7	435
	Std	0.03	1.2	1.0	0.9					0.1	2.5	60	0.4	55
D2	Min	0	0	1.5	0	0	0	0	0	0	0	300	0.01	264
	Max	0.09	15.0	18.9	5.3	1.3	12	3.3	0.02	1.9	20	600	500	641
	Mean	0.02	6.1	5.1	2.5	0.6	4.0	0.1	0	0.4	5.8	484	23.5	433
	Std	0.02	6.3	3.8	2.0	0.5	4.6	0.5	0	0.5	6.7	50	55.3	74

Fig. 1. Prediction of results in the literature: (a) predicted hardness vs. experimental hardness; (b) the ratio of MAE value to mean hardness, i.e., R value.

Fig. 2. Prediction results for a new dataset, i.e., R-phase, using the (a) GA-GRR model and (b) GA-WMOS model.

Fig. 3. Prediction results for the new dataset, i.e., R-phase, using PM models with the maximal prediction accuracy: (a) GA-GRR model and (b) GA-WMOS model. The prediction results of testing set using ML models: (c) RFR and (d) SVR.

Fig. 4. Prediction results for a complex dataset containing various marageing steels via PM models: (a) GA-GRR model; (b) GA-WMOS model; The prediction results of testing set using ML models: (c) RFR model; (d) SVR model.

Fig. 5. Semi-quantitative analysis of the prediction accuracy of ML and PM methods.

Fig. 6. Prediction results of the PM model constructed by each alloy system: (a) GA-GRR model and (b) GA-WMOS model. The spatial distribution of PM parameters for the (c) GA-GRR model and (d) GA-WMOS model as a result of applying the t-SNE algorithm. The decreased MAE value when modeling for each alloy system compared to that when modeling for the whole R-phase dataset: (e) GA-GRR model, (f) GA-WMOS model.

Fig. 7. Parameters and parameter acquisition for the ML model and PM model.

Fig. 8. Prediction accuracy varies with the number of alloy systems for PM and ML models.

Fig. 9. Prediction process of the PM model and ML model.

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