End-to-end symmetry preserving inter-atomic potential energy model for finite and extended systems
Author(s): Zhang, Linfeng; Han, Jiequn; Wang, Han; Saidi, Wissam; Car, Roberto; et al
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http://arks.princeton.edu/ark:/88435/pr1df6k37z| Abstract: | Machine learning models are changing the paradigm of molecular modeling, which is a fundamental tool for material science, chemistry, and computational biology. Of particular interest is the inter-atomic potential energy surface (PES). Here we develop Deep Potential - Smooth Edition (DeepPot-SE), an end-to-end machine learning-based PES model, which is able to efficiently represent the PES of a wide variety of systems with the accuracy of ab initio quantum mechanics models. By construction, DeepPot-SE is extensive and continuously differentiable, scales linearly with system size, and preserves all the natural symmetries of the system. Further, we show that DeepPot-SE describes finite and extended systems including organic molecules, metals, semiconductors, and insulators with high fidelity. |
| Publication Date: | 3-Dec-2018 |
| Citation: | Zhang, L, Han, J, Wang, H, Saidi, WA, Car, R, Weinan, E. (2018). End-to-end symmetry preserving inter-atomic potential energy model for finite and extended systems. Advances in Neural Information Processing Systems, 2018-December (4436 - 4446) |
| ISSN: | 1049-5258 |
| Pages: | 4436 - 4446 |
| Type of Material: | Conference Article |
| Journal/Proceeding Title: | NIPS'18: Proceedings of the 32nd International Conference on Neural Information Processing Systems |
| Version: | Author's manuscript |
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