Daniel R. Cassar scite author profile

The temperature at which the classical critical nucleus size is equal to the average size of the cooperatively rearranging regions (CRR) in a supercooled liquid has been referred to as a "cross-over" temperature. We show, for the first time, using published nucleation rate, viscosity, and thermo-physical data, that the cross-over temperature for the lithium disilicate melt is significantly larger than the temperature of the kinetic spinodal and is equal or close to the temperature corresponding to the maximum in the experimentally observed nucleation rates. We suggest that the abnormal decrease in nucleation rates below the cross-over temperature is most likely because, in this regime, the CRR size controls the critical nucleus size and the nucleation rate. This finding links, for the first time, measured nucleation kinetics to the dynamic heterogeneities in a supercooled liquid.

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Crystal growth and viscous flow in barium disilicate glass

Rodrigues

Cassar

Fokin

et al. 2018

Journal of Non-Crystalline Solids

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Explainable Machine Learning Algorithms For Predicting Glass Transition Temperatures

et al. 2020

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Daniel R. Cassar

Crystal nucleation in glass-forming liquids: Variation of the size of the “structural units” with temperature

Predicting glass transition temperatures using neural networks

Role of dynamic heterogeneities in crystal nucleation kinetics in an oxide supercooled liquid

Crystal growth and viscous flow in barium disilicate glass

Explainable Machine Learning Algorithms For Predicting Glass Transition Temperatures

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