REFERENCES

1. Liu, H.; Cheng, Z.; Yu, W.; Zhou, Z.; Cheng, L.; Cai, Q. Effect of high-temperature reduction pretreatment on internal quality of 42CrMo casting billet. J. Iron. Steel. Res. Int. 2020, 28, 693-702.

2. Li, G.; Ji, C.; Zhu, M. Prediction of internal crack initiation in continuously cast blooms. Metall. Mater. Trans. B. 2021, 52, 1164-78.

3. Kong, Y.; Chen, D.; Liu, Q.; Long, M. A prediction model for internal cracks during slab continuous casting. Metals 2019, 9, 587.

4. Thomas, B. G. Review on modeling and simulation of continuous casting. Steel. Res. Int. 2017, 89, 1700312.

5. Jiang, D.; Wang, W.; Luo, S.; Ji, C.; Zhu, M. Mechanism of macrosegregation formation in continuous casting slab: a numerical simulation study. Metall. Mater. Trans. B. 2017, 48, 3120-31.

6. Sun, H.; Zhang, J. Study on the Macrosegregation behavior for the bloom continuous casting: model development and validation. Metall. Mater. Trans. B. 2013, 45, 1133-49.

7. Zhang, Z.; Wu, M.; Zhang, H.; et al. Modeling of the as-cast structure and macrosegregation in the continuous casting of a steel billet: Effect of M-EMS. J. Mater. Process. Technol. 2022, 301, 117434.

8. Dong, Q.; Zhang, J.; Qian, L.; Yin, Y. Numerical modeling of macrosegregation in round billet with different microsegregation models. ISIJ. Int. 2017, 57, 814-23.

9. Hatič, V.; Mavrič, B.; Šarler, B. Simulation of macrosegregation in direct-chill casting - A model based on meshless diffuse approximate method. Eng. Anal. Boundary. Elem. 2020, 113, 191-203.

10. Geng, X.; Wang, F.; Wu, H. H.; et al. Data-driven and artificial intelligence accelerated steel material research and intelligent manufacturing technology. MGE. Advances. 2023, 1, e10.

11. Wang, H.; Gao, S.; Wang, B.; et al. Recent advances in machine learning-assisted fatigue life prediction of additive manufactured metallic materials: a review. J. Mater. Sci. Technol. 2024, 198, 111-36.

12. Zhang, N.; He, A.; Zhang, G.; et al. Interpretable machine learning-assisted design of Fe-based nanocrystalline alloys with high saturation magnetic induction and low coercivity. J. Mater. Sci. Technol. 2024, 188, 73-83.

13. Zhang, Y.; Ren, K.; Wang, W. Y.; et al. Discovering the ultralow thermal conductive A₂B₂O₇-type high-entropy oxides through the hybrid knowledge-assisted data-driven machine learning. J. Mater. Sci. Technol. 2024, 168, 131-42.

14. Zhang, Y.; Wen, C.; Dang, P.; Lookman, T.; Xue, D.; Su, Y. Toward ultra-high strength high entropy alloys via feature engineering. J. Mater. Sci. Technol. 2024, 200, 243-52.

15. Wang, C.; Fu, H.; Jiang, L.; Xue, D.; Xie, J. A property-oriented design strategy for high performance copper alloys via machine learning. NPJ. Comput. Mater. 2019, 5, 87.

16. Song, K.; Yan, F.; Ding, T.; Gao, L.; Lu, S. A steel property optimization model based on the XGBoost algorithm and improved PSO. Comput. Mater. Sci.。. 2020, 174, 109472.

17. Wen, C.; Zhang, Y.; Wang, C.; et al. Machine learning assisted design of high entropy alloys with desired property. Acta. Mater. 2019, 170, 109-17.

18. Wu, Q.; Wang, Z.; Hu, X.; et al. Uncovering the eutectics design by machine learning in the Al–Co–Cr–Fe–Ni high entropy system. Acta. Mater. 2020, 182, 278-86.

19. Liu, Y.; Wu, J.; Wang, Z.; et al. Predicting creep rupture life of Ni-based single crystal superalloys using divide-and-conquer approach based machine learning. Acta. Mater. 2020, 195, 454-67.

20. Li, S.; Dong, Z.; Jin, J.; et al. Optimal design of high-performance rare-earth-free wrought magnesium alloys using machine learning. MGE. Advances. 2024, 2, e45.

21. Shi, B.; Lookman, T.; Xue, D. Multi-objective optimization and its application in materials science. MGE. Advances. 2023, 1, e14.

22. Gou, W.; Shi, Z. Z.; Zhu, Y.; et al. Multi-objective optimization of three mechanical properties of Mg alloys through machine learning. MGE. Advances. 2024, 2, e54.

23. Zou, L.; Zhang, J.; Liu, Q.; Zeng, F.; Chen, J.; Guan, M. Prediction of central carbon segregation in continuous casting billet using a regularized extreme learning machine model. Metals 2019, 9, 1312.

24. Zou, L.; Zhang, J.; Han, Y.; Zeng, F.; Li, Q.; Liu, Q. Internal crack prediction of continuous casting billet based on principal component analysis and deep neural network. Metals 2021, 11, 1976.

25. Xu, Z.; Liu, X.; Zhang, K. Mechanical properties prediction for hot rolled alloy steel using convolutional neural network. IEEE. Access. 2019, 7, 47068-78.

26. Zhang, Q.; Wang, Y. Research on mechanical property prediction of hot rolled steel based on lightweight multi-branch convolutional neural network. Mater. Today. Commun. 2023, 37, 107445.

27. Ma, Y.; Deng, C.; Sun, Z.; Gong, B.; Liu, Y. Prediction of sequential stress-strain fields in dual-phase steels via convolutional neural network. Mater. Today. Commun. 2025, 46, 112645.

28. Zhu, L.; Luo, Q.; Chen, Q.; et al. Prediction of ultimate tensile strength of Al-Si alloys based on multimodal fusion learning. MGE. Advances. 2024, 2, e26.

29. Wang, W. Y.; Zhang, S.; Li, G.; et al. Artificial intelligence enabled smart design and manufacturing of advanced materials: the endless Frontier in AI⁺ era. MGE. Advances. 2024, 2, e56.

30. Zong, B.; Li, J.; Zhou, C.; Wang, P.; Tang, B.; Yuan, R. Enhancing creep rupture life prediction of high-temperature titanium alloys using convolutional neural networks. MGE. Advances. 2024, 2, e68.

31. Xu, N.; Wang, L.; Hu, J.; et al. Enabling strong and formable advanced high-strength steels through inherited homogeneous microstructure. Scr. Mater. 2025, 259, 116560.

32. Yang, Z.; Li, Y.; Wei, X.; Wang, X.; Wang, C. Martensite start temperature prediction through a deep learning strategy using both microstructure images and composition data. Materials. (Basel). 2023, 16, 932.

33. Lee, S. Y.; Tama, B. A.; Choi, C.; Hwang, J.; Bang, J.; Lee, S. Spatial and sequential deep learning approach for predicting temperature distribution in a steel-making continuous casting process. IEEE. Access. 2020, 8, 21953-65.

34. Lu, Z.; Ren, N.; Xu, X.; et al. Real-time prediction and adaptive adjustment of continuous casting based on deep learning. Commun. Eng. 2023, 2, 34.

35. Lian, G.; Sun, Q.; Liu, X.; et al. Automatic recognition and intelligent analysis of central shrinkage defects of continuous casting billets based on deep learning. J. Iron. Steel. Res. Int. 2023, 30, 937-48.

36. Wei, X.; Van Der Zwaag, S.; Jia, Z.; Wang, C.; Xu, W. On the use of transfer modeling to design new steels with excellent rotating bending fatigue resistance even in the case of very small calibration datasets. Acta. Mater. 2022, 235, 118103.

37. Selvaraju, R. R.; Cogswell, M.; Das, A.; Vedantam, R.; Parikh, D.; Batra, D. Grad-CAM: Visual Explanations from Deep Networks via Gradient-Based Localization. In 2017 IEEE International Conference on Computer Vision (ICCV), Venice, October 22-29, 2017; IEEE, 2017, pp 618-26.