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Dielectric tensor of perovskite oxides at finite temperature using equivariant graph neural network potentials

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arxiv 2412.03541 v1 pith:D4NXJJNW submitted 2024-12-04 cond-mat.mtrl-sci physics.comp-ph

Dielectric tensor of perovskite oxides at finite temperature using equivariant graph neural network potentials

classification cond-mat.mtrl-sci physics.comp-ph
keywords modelsfinitetemperaturedemonstratedielectricefficientequivariantgraph
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Atomistic simulations of properties of materials at finite temperatures are computationally demanding and require models that are more efficient than the ab initio approaches. Machine learning (ML) and artificial intelligence (AI) address this issue by enabling accurate models with close to ab initio accuracy. Here, we demonstrate the utility of ML models in capturing properties of realistic materials by performing finite temperature molecular dynamics simulations of perovskite oxides using a force field based on equivariant graph neural networks. The models demonstrate efficient learning from a small training dataset of energies, forces, stresses, and tensors of Born effective charges. We qualitatively capture the temperature dependence of the dielectric tensor and structural phase transitions in calcium titanate.

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