February 8, 2023
Journal Article

Predicting initial dissolution rates using structural features from molecular dynamics simulations

Abstract

Predicting chemical durability of glass materials is important for various applications from daily life such as drink glass and kitchen ware to advanced technologies such as nuclear waste disposal and biomedicine. In this work, we explored prediction of initial dissolution rate through structural features from molecular dynamics (MD) simulations for a wide range of glass compositions (total 28) including borosilicate and aluminosilicate glasses, ZrO2-containing and V2O5-containing boroaluminosilicate glasses. The initial dissolution rates (r0) measured experimentally at 90 °C with varying solution conditions were correlated with structural features (e.g., polyhedral linkages and non-bridging oxygen species) obtained from MD simulations, either from this study or from literature. Since hydrolysis of the glass network through breaking of the network former linkages (e.g., Si-O-Si, Si-O-Al, etc.) is a critical step of network glass dissolution, the statistics of these linkages obtained from MD were correlated to r0 through linear regression, where the coefficient of determination (R2) and root mean square error are found to be 0.949 and 0.681, respectively. This model was compared and discussed with existing models developed by various approaches including machine learning, the kinetic rate equation, topological constraint theory, and other descriptors from MD simulations. The discussion provides insights on future model improvements to predict glass dissolution. In addition, the impact of V2O5 on the glass dissolution was examined in detail, implicating that the impact is not the same across all glass compositions and test conditions.

Published: February 8, 2023

Citation

Lu X., L. Deng, S. Gin, B. Parruzot, J. Reiser, J.V. Ryan, and J.D. Vienna, et al. 2023. Predicting initial dissolution rates using structural features from molecular dynamics simulations. Journal of the American Ceramic Society 106, no. 2:1025–1036. PNNL-SA-176987. doi:10.1111/jace.18850

Research topics