SchNet – A deep learning architecture for molecules and materials

Schütt, K. T.; Sauceda, Huziel E.; Kindermans, P.-J.; Tkatchenko, Alexandre; Müller, Klaus-Robert

doi:10.1063/1.5019779

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SchNet – A deep learning architecture for molecules and materials

Schütt, K. T., Sauceda, H. E., Kindermans, P.-J., Tkatchenko, A., & Müller, K.-R. (2018). SchNet – A deep learning architecture for molecules and materials. The Journal of Chemical Physics, 148(24): 241722. doi:10.1063/1.5019779.

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Item Permalink: https://hdl.handle.net/21.11116/0000-0001-3BD6-C Version Permalink: https://hdl.handle.net/21.11116/0000-0001-4FE6-4

Genre: Journal Article

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Creators:
Schütt, K. T.¹, Author
Sauceda, Huziel E.², Author
Kindermans, P.-J.¹, Author
Tkatchenko, Alexandre³, Author
Müller, Klaus-Robert^{1, 4, 5}, Author

Affiliations:
1Machine Learning Group, Technische Universität Berlin, 10587 Berlin, Germany, ou_persistent22
2Theory, Fritz Haber Institute, Max Planck Society, ou_634547
3Physics and Materials Science Research Unit, University of Luxembourg, ou_persistent22
4Computational Biology and Applied Algorithmics, MPI for Informatics, Max Planck Society, ou_40046
5Department of Brain and Cognitive Engineering, Korea University, Anam-dong, Seongbuk-gu, Seoul 136-713, South Korea, ou_persistent22

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Abstract: Deep learning has led to a paradigm shift in artificial intelligence, including web, text, and image search, speech recognition, as well as bioinformatics, with growing impact in chemical physics. Machine learning, in general, and deep learning, in particular, are ideally suitable for representing quantum-mechanical interactions, enabling us to model nonlinear potential-energy surfaces or enhancing the exploration of chemical compound space. Here we present the deep learning architecture SchNet that is specifically designed to model atomistic systems by making use of continuous-filter convolutional layers. We demonstrate the capabilities of SchNet by accurately predicting a range of properties across chemical space for molecules and materials, where our model learns chemically plausible embeddings of atom types across the periodic table. Finally, we employ SchNet to predict potential-energy surfaces and energy-conserving force fields for molecular dynamics simulations of small molecules and perform an exemplary study on the quantum-mechanical properties of C₂₀-fullerene that would have been infeasible with regular ab initio molecular dynamics.

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Language(s): eng - English

Dates: Submitted: 2017-12-16Accepted: 2018-03-08Published Online: 2018-03-29Date issued: 2018-06-18

Publication Status: Issued

Pages: 11

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Table of Contents: -

Rev. Type: Peer

Identifiers: DOI: 10.1063/1.5019779

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Project name : BeStMo - Beyond Static Molecules: Modeling Quantum Fluctuations in Complex Molecular Environments

Grant ID : 725291

Funding program : Horizon 2020 (H2020)

Funding organization : European Commission (EC)

Project name : ZERO-TRAIN-BCI - Combining constrained based learning and transfer learning to facilitate Zero-training Brain-Computer Interfacing

Grant ID : 657679

Funding program : Horizon 2020 (H2020)

Funding organization : European Commission (EC)

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Title: The Journal of Chemical Physics

Other : J. Chem. Phys.

Source Genre: Journal

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Publ. Info: Woodbury, N.Y. : American Institute of Physics

Pages: 11 Volume / Issue: 148 (24) Sequence Number: 241722 Start / End Page: - Identifier: ISSN: 0021-9606
CoNE: https://pure.mpg.de/cone/journals/resource/954922836226