Accurate prediction of high-temperature ionic melt viscosity through data-driven modeling enhanced with explainable AI

doi:10.1016/j.jmst.2025.06.012

Abstract

Abstract: The increasing demand for high-performance steels and environmentally sustainable pyrometallurgical processes has led to significant compositional variations in ionic melts and the development of novel fluxes. Optimizing ionic melt performance requires precise control of thermophysical properties, with viscosity being a key factor influencing heat and mass transport in various industrial applications. However, traditional experimental and analytical methods are often cost-prohibitive and pose challenges in generalizing findings across diverse compositions and temperatures. This study introduces MOVINet (MOlten ions VIscosity Network), a data-driven modeling framework designed to predict high-temperature ionic melt viscosity based on melt composition, temperature, and fundamental properties of 13 components, including 12 oxides and one fluoride. Trained on 1981 experimentally measured data points and evaluated using 480 independent data points, MOVINet achieved a mean absolute error (MAE) of 0.1480, reducing error by 57.7 % compared to the best existing model (MAE = 0.3497). It consistently demonstrated high accuracy across six ionic melt types over a broad temperature range (1100-1870 °C) and maintained low errors even for melts containing previously unseen components (e.g., MAEs of 0.0567 for CaCl₂ and 0.1463 for BaO-containing samples). Furthermore, explainable AI analysis confirmed the dominant influence of temperature while highlighting compositional features affecting viscosity.

Key words: Viscosity, Ionic melts, Neural network, Data-driven approach, Explainable AI

Seungyeon Lee, Sanghoon Lee, Il Sohn. Accurate prediction of high-temperature ionic melt viscosity through data-driven modeling enhanced with explainable AI[J]. J. Mater. Sci. Technol., 2026, 248: 110-118.

References

[1] Emergen Research, High Strength Steel Market: Analysis and forecast (2024-2033), https://www.emergenresearch.com/industry-report/ high- strength- steel- market , May 25, 2025.
[2] Z. Wang, I. Sohn, J. Iron Steel Inst. Jpn. 107(2021) 1-14.
[3] Z. Chen, W. Du, M. Zhang, Q. Wang, S. He, ISIJ Int. 61(2021) 814-823.
[4] H.C. Wang, G.D. Bao, S. Sadaf, S.S. Mao, T. Wu, J. Min. Metall.Sect. B-Metall. 59(2023) 507-514.
[5] W. Wang, D. Cai, L. Zhang, I. Sohn, Steel Res. Int. 92 (2021) 2000314.
[6] L.V. Fisher, A.R. Barron, Resour. Conserv. Recycl. 146(2019) 244-255.
[7] J. Zhao, P. Yan, D. Wang, J. Clean. Prod. 156(2017) 50-61.
[8] G.H. Kim, I. Sohn, Metall. Mater. Trans. B 45 (2014) 86-95.
[9] M.S. Seo, I. Sohn, J. Am. Ceram.Soc. 102(2019) 6275-6283.
[10] S. Mo, J. Zeng, H. Zhang, Y. Wu, T. Liu, H. Ni, J. Mater. Sci.Technol. 143(2023) 189-197.
[11] S. Seetharaman, D. Sichen, Metall. Mater. Trans. B 25 (1994) 589-595.
[12] D. Sichen, J. Bygd’en, S. Seetharaman, Metall. Mater. Trans. B 25 (1994) 519-525.
[13] W.L.McCauley, D.Apelian, Can. Metall. Q. 20(1981) 247-262.
[14] A. Kondratiev, E. Jak, P.C. Hayes, JOM 54 (2002) 41-45.
[15] H.R. Shaw, Am. J. Sci. 272(1972) 870-893.
[16] K.C. Mills, S. Sridhar, Ironmak. Steelmak. 26(1999) 262-268.
[17] G. Urbain, M. Boiret, Ironmak. Steelmak. 17(1990) 255-260.
[18] P.V. Riboud, Y. Roux, L.-D. Lucas, H.Gaye, Fachber. Hüttenprax. Metallweiterverarb. 19(1981) 859-869.
[19] A. Kondratiev, E. Jak, Metall. Mater. Trans. B 32 (2001) 1015-1025.
[20] L. Zhang, S. Jahanshahi, Metall. Mater. Trans. B 29 (1998) 177-186.
[21] H. Hu, R.G. Reddy, High Temp. Sci. 28(1988) 195-202.
[22] T. Iida, H. Sakai, Y. Kita, K. Shigeno, ISIJ Int. 40(2000) 110-114.
[23] P. Richet, Geochim. Cosmochim. Acta 48 (1984) 471-483.
[24] G. Khalaj, M.J. Khalaj, J. Intell.Fuzzy Syst. 26(2014) 2229-2237.
[25] G. Khalaj, M.-J. Khalaj, Neural Comput.Appl. 24(2014) 685-694.
[26] C. Reddy, R. Kumar, P. Chakraborty, B. Karmakar, S. Pottipati, A. Kundu, B.-H. Jeon, Chem.Eng. J. 492(2024) 152272.
[27] G. Khalaj, M. Khoeini, M. Khakian-Qomi, Neural Comput. Appl. 23(2012) 769-777.
[28] P. Peng, Y. Peng, F. Liu, S. Long, C. Zhang, A. Tang, J. She, J. Zhang, F. Pan, J. Mater. Sci.Technol. 238(2025) 132-145.
[29] G. Khalaj, A. Nazari, H. Pouraliakbar, Neural Netw. World 23 (2013) 117-130.
[30] G. Khalaj, H. Pouraliakbar, K. Rahimi Mamaghani, M. Khalaj, Neural Netw. World 23 (2013) 351-367.
[31] A. Nazari, G. Khalaj, S. Riahi, Math. Comput. Model. 55(2012) 1339-1353.
[32] G. Khalaj, H. Pouraliakbar, Ceram. Int. 40(2014) 5515-5522.
[33] C. Pei, Q. Ma, J. Zhang, L. Yu, H. Li, Q. Gao, J. Xiong, J. Mater. Sci.Technol. 235(2025) 232-243.
[34] G. Khalaj, M.-J. Khalaj, Int.J. Mater. Res. 104(2013) 697-702.
[35] M.A .Duchesne, A . MacChi, D.Y. Lu, R.W. Hughes, D. McCalden, E.J. Anthony, Fuel Process. Technol. 91(2010) 831-836.
[36] Z. Chen, M. Wang, Z. Meng, H. Wang, L. Liu, X. Wang, Ceram. Int. 47(2021) 30691-30701.
[37] D.R. Cassar, Acta Mater. 206(2021) 116602.
[38] C.A. Angell, J. Non-Cryst. Solids 131 (1991) 13-31.
[39] H. Vogel, Phys. Z. 22(1921) 645-646.
[40] G.S. Fulcher, J. Am. Ceram.Soc. 8(1925) 339-355.
[41] G. Tammann, W. Hesse, Z. Anorg. Allg.Chem. 156(1926) 245-257.
[42] G. Cybenko, Math. Control Signals Syst. 2(1989) 303-314.
[43] K. Hornik, M. Stinchcombe, H. White, Neural Netw. 2(1989) 359-366.
[44] J. Mao, A.K. Jain, IEEE Trans. Neural Netw. 6(1995) 296-317.
[45] B. Lerner, H. Guterman, M. Aladjem, I. Dinstein, Pattern Recognit. Lett. 20(1999) 7-14.
[46] A. Barredo Arrieta, N. Díaz-Rodríguez, J. Del Ser, A. Bennetot, S. Tabik, A. Barbado, S. Garcia, S. GilLopez, D. Molina, R. Benjamins, R. Chatila, F. Herrera, Inf. Fusion 58 (2020) 82-115.
[47] F. Oviedo, J. Lavista Ferres, T. Buonassisi, K.T. Butler, Acc. Mater. Res. 3(2022) 597-607.
[48] X. Zhong, B. Gallagher, S. Liu, B. Kailkhura, A. Hiszpanski, T.Y. Han, NPJ Comput. Mater. 8(2022) 204.
[49] G. Pilania, Comput. Mater. Sci. 193(2021) 110360.
[50] S.M. Lundberg, S.I.Lee, in: Proceedings of the 30th Conference on Neural Information Processing Systems, Long Beach, CA, U.S., 2017, pp. 4-9.
[51] A. Altmann, L. Tolos¸ i, O. Sander, T. Lengauer, Bioinformatics 26 (2010) 1340-1347.
[52] F.G. Ely, D.H. Barnhart, Chemistry of Coal Utilization, John Wiley & Sons, 1963.
[53] Y. Waseda, J.M.Toguri, in: The Structure and Properties of Oxide Melts, World Scientific, Singapore, 1998, pp. 2-4.
[54] Ł. Mentel, Mendeleev-A Python resource for properties of chemical elements, ions and isotopes 25 (May) (2025) . https://github.com/lmmentel/mendeleev.
[55] A. Jain, S.P. Ong, G. Hautier, W. Chen, W.D. Richards, S. Dacek, S. Cholia, D. Gunter, D. Skinner, G. Ceder, K.A. Persson, APL Mater. 1(2013) 011002.
[56] C.W. Bale, P. Chartrand, S.A. Degterov, G. Eriksson, K. Hack, R. Ben Mahfoud, J. Melançon, A.D. Pelton, S. Petersen, Calphad 26 (2002) 189-228.
[57] L. Huang, J. Qin, Y. Zhou, F. Zhu, L. Liu, L. Shao, IEEE Trans. Pattern Anal. Mach. Intell. 45(2023) 10173-10196.
[58] Agarap, Abien Fred., arXiv:1803.08375.
[59] C. Szegedy, S. Ioffe, V. Vanhoucke, A. Alemi, in: Proceedings of the 31st AAAI Conference on Artificial Intelligence, San Francisco, California, U.S., 2017.
[60] N. Srivastava, G. Hinton, A. Krizhevsky, I. Sutskever, R. Salakhutdinov, J. Mach. Learn.Res. 15(2014) 1929-1958.
[61] J. Snoek, H. Larochelle, R.P.Adams, in: Proceedings of the 25th Conference on Neural Information Processing Systems, Lake Tahoe, NV, U.S., 2012.
[62] L. Yang, A. Shami, Neurocomputing 415 (2020) 295-316.
[63] T.M. Dutschmann, L. Kinzel, A. ter Laak, K.Baumann, J. Cheminform. 15(2023) 49.
[64] M.A. Ganaie, M. Hu, A.K. Malik, M. Tanveer, P.N. Suganthan, Eng. Appl. Artif. Intell. 115(2022) 105151.
[65] G.H. Kim, I. Sohn, J. Am. Ceram.Soc. 102(2019) 6575-6590.
[66] L. Zhang, W. Wang, S. Xie, K. Zhang, I. Sohn, J. Non-Cryst. Solids 460 (2017) 113-118.
[67] X. Wan, C. Shi, Y. Huang, Q. Shu, Y. Zhao, Metall. Mater. Trans. B 54 (2023) 465-479.
[68] C. Wang, J. Zhang, Z. Liu, K. Jiao, G. Wang, J. Yang, K. Chou, Metall. Mater. Trans. B 48 (2017) 328-334 .