AI Article Synopsis
- Molecular simulations have advanced our understanding of ice nucleation, traditionally challenging due to the high computational costs of first-principles calculations.
- A novel machine-learning model has been developed to efficiently estimate nucleation rates at atmospheric pressure and varying supercoolings using density-functional theory energies and forces.
- The study successfully computes the size of critical clusters for nucleation, aligning results with experimental data and exploring factors like driving force and interfacial free energy's impact on nucleation rates.
Article Abstract
Molecular simulations have provided valuable insight into the microscopic mechanisms underlying homogeneous ice nucleation. While empirical models have been used extensively to study this phenomenon, simulations based on first-principles calculations have so far proven prohibitively expensive. Here, we circumvent this difficulty by using an efficient machine-learning model trained on density-functional theory energies and forces. We compute nucleation rates at atmospheric pressure, over a broad range of supercoolings, using the seeding technique and systems of up to hundreds of thousands of atoms simulated with ab initio accuracy. The key quantity provided by the seeding technique is the size of the critical cluster (i.e., a size such that the cluster has equal probabilities of growing or melting at the given supersaturation), which is used together with the equations of classical nucleation theory to compute nucleation rates. We find that nucleation rates for our model at moderate supercoolings are in good agreement with experimental measurements within the error of our calculation. We also study the impact of properties such as the thermodynamic driving force, interfacial free energy, and stacking disorder on the calculated rates.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9388152 | PMC |
| http://dx.doi.org/10.1073/pnas.2207294119 | DOI Listing |
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