Tyler Del Rose scite author profile

Chemical design of SiO2-based glasses with high elastic moduli and low weight is of great interest. However, it is difficult to find a universal expression to predict the elastic moduli according to the glass composition before synthesis since the elastic moduli are a complex function of interatomic bonds and their ordering at different length scales.Here we show that the densities and elastic moduli of SiO2-based glasses can be efficiently predicted by machine learning (ML) techniques across a complex compositional space with multiple (>10) types of additive oxides besides SiO2. Our machine learning approach relies on a training set generated by high-throughput molecular dynamic (MD) simulations, a set of elaborately constructed descriptors that bridges the empirical statistical modeling with the fundamental physics of interatomic bonding, and a statistical learning/predicting model developed by implementing least absolute shrinkage and selection operator with a gradient boost machine (GBM-LASSO). The predictions of the ML model are comprehensively compared and validated with a large amount of both simulation and experimental data. By just training with a dataset only composed of binary and ternary glass samples, our model shows very promising capabilities to predict the density and elastic moduli for k-nary SiO2based glasses beyond the training set. As an example of its potential applications, our GBM-LASSO model was used to perform a rapid and low-cost screening of many (~10 5 ) compositions of a multicomponent glass system to construct a compositionalproperty database that allows for a fruitful overview on the glass density and elastic properties.

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Machine-learning enabled thermodynamic model for the design of new rare-earth compounds

Singh

Rose

Vazquez

et al. 2022

Acta Materialia

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Hidden first-order phase transitions and large magnetocaloric effects in GdNi1−xCox

Biswas

Rose

Mudryk

et al. 2022

Journal of Alloys and Compounds

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Tyler Del Rose

Predicting densities and elastic moduli of SiO2-based glasses by machine learning

Machine-learning enabled thermodynamic model for the design of new rare-earth compounds

Hidden first-order phase transitions and large magnetocaloric effects in GdNi1−xCox

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