Volume 107, Issue 12 p. 7784-7799
SPECIAL ISSUE ARTICLE

Evaluation of GlassNet for physics-informed machine learning of glass stability and glass-forming ability

Sarah I. Allec

Sarah I. Allec

Citrine Informatics, Redwood City, California, USA

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Xiaonan Lu

Xiaonan Lu

Pacific Northwest National Laboratory, Richland, Washington, USA

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Daniel R. Cassar

Daniel R. Cassar

Ilum School of Science, Brazilian Center for Research in Energy and Materials (CNPEM), Sao Paulo, Brazil

National Institute of Science and Technology on Materials Informatics, Sao Paulo, Brazil

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Xuan T. Nguyen

Xuan T. Nguyen

The Department of Materials Science and Engineering, University of North Texas, Denton, Texas, USA

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Vinay I. Hegde

Vinay I. Hegde

Citrine Informatics, Redwood City, California, USA

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Thiruvillamalai Mahadevan

Thiruvillamalai Mahadevan

The Department of Materials Science and Engineering, University of North Texas, Denton, Texas, USA

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Miroslava Peterson

Miroslava Peterson

Pacific Northwest National Laboratory, Richland, Washington, USA

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Jincheng Du

Jincheng Du

The Department of Materials Science and Engineering, University of North Texas, Denton, Texas, USA

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Brian J. Riley

Brian J. Riley

Pacific Northwest National Laboratory, Richland, Washington, USA

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John D. Vienna

John D. Vienna

Pacific Northwest National Laboratory, Richland, Washington, USA

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James E. Saal

Corresponding Author

James E. Saal

Citrine Informatics, Redwood City, California, USA

Correspondence

James E. Saal, Citrine Informatics, Redwood City, CA 94063, USA.

Email: [email protected]

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First published: 11 June 2024
Citations: 1

Abstract

Glassy materials form the basis of many modern applications, including nuclear waste immobilization, touch-screen displays, and optical fibers, and also hold great potential for future medical and environmental applications. However, their structural complexity and large composition space make design and optimization challenging for certain applications. Of particular importance for glass processing and design is an estimate of a given composition's glass-forming ability (GFA). However, there remain many open questions regarding the underlying physical mechanisms of glass formation, especially in oxide glasses. It is apparent that a proxy for GFA would be highly useful in glass processing and design, but identifying such a surrogate property has proven itself to be difficult. While glass stability (GS) parameters have historically been used as a GFA surrogate, recent research has demonstrated that most of these parameters are not accurate predictors of the GFA of oxide glasses. Here, we explore the application of an open-source pre-trained neural network model, GlassNet, that can predict the characteristic temperatures necessary to compute GS with reasonable performance and assess the feasibility of using these physics-informed machine learning (PIML)-predicted GS parameters to estimate GFA. In doing so, we track the uncertainties at each step of the computation—from the original ML prediction errors to the compounding of errors during GS estimation, and finally to the final estimation of GFA. While GlassNet exhibits reasonable accuracy on all individual properties, we observe a large compounding of error in the combination of these individual predictions for the PIML prediction of GS, finding that random forest models offer similar accuracy to GlassNet. We also break down the performance of GlassNet on different glass families and find that the error in GS prediction is correlated with the error in crystallization peak temperature prediction. Lastly, we utilize this finding to assess the relationship between top-performing GS parameters and GFA for two ternary glass systems: sodium borosilicate and sodium iron phosphate glasses. We conclude that to obtain true ML predictive capability of GFA, significantly more data needs to be collected.