Accurate large-scale simulations of siliceous zeolites by neural network potentials
Publication date
2022Published in
npj Computational MaterialsVolume / Issue
8 (1)ISBN / ISSN
ISSN: 2057-3960Metadata
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This publication has a published version with DOI 10.1038/s41524-022-00865-w
Abstract
The computational discovery and design of zeolites is a crucial part of the chemical industry. Finding highly accurate while computational feasible protocol for identification of hypothetical siliceous frameworks that could be targeted experimentally is a great challenge. To tackle this challenge, we trained neural network potentials (NNP) with the SchNet architecture on a structurally diverse database of density functional theory (DFT) data. This database was iteratively extended by active learning to cover not only low-energy equilibrium configurations but also high-energy transition states. We demonstrate that the resulting reactive NNPs retain DFT accuracy for thermodynamic stabilities, vibrational properties, as well as reactive and non-reactive phase transformations. As a showcase, we screened an existing zeolite database and revealed >20k additional hypothetical frameworks in the thermodynamically accessible range of zeolite synthesis. Hence, our NNPs are expected to be essential for future high-throughput studies on the structure and reactivity of siliceous zeolites.
Keywords
initio molecular-dynamics, total-energy calculations, phase-transition, frequency modes, frameworks, temperature, cristobalite, dispersion, stability, pressure
Permanent link
https://hdl.handle.net/20.500.14178/1899License
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