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| Autori principali: | , , , , , , , , , |
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| Natura: | Preprint |
| Pubblicazione: |
2019
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| Soggetti: | |
| Accesso online: | https://arxiv.org/abs/1909.12963 |
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| _version_ | 1866910492130279424 |
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| author | Zubatyuk, Tetiana Nebgen, Ben Lubbers, Nicholas Smith, Justin S. Zubatyuk, Roman Zhou, Guoqing Koh, Christopher Barros, Kipton Isayev, Olexandr Tretiak, Sergei |
| author_facet | Zubatyuk, Tetiana Nebgen, Ben Lubbers, Nicholas Smith, Justin S. Zubatyuk, Roman Zhou, Guoqing Koh, Christopher Barros, Kipton Isayev, Olexandr Tretiak, Sergei |
| contents | The Hückel Hamiltonian is an incredibly simple tight-binding model famed for its ability to capture qualitative physics phenomena arising from electron interactions in molecules and materials. Part of its simplicity arises from using only two types of empirically fit physics-motivated parameters: the first describes the orbital energies on each atom and the second describes electronic interactions and bonding between atoms. By replacing these traditionally static parameters with dynamically predicted values, we vastly increase the accuracy of the extended Hückel model. The dynamic values are generated with a deep neural network, which is trained to reproduce orbital energies and densities derived from density functional theory. The resulting model retains interpretability while the deep neural network parameterization is smooth, accurate, and reproduces insightful features of the original static parameterization. Finally, we demonstrate that the Hückel model, and not the deep neural network, is responsible for capturing intricate orbital interactions in two molecular case studies. Overall, this work shows the promise of utilizing machine learning to formulate simple, accurate, and dynamically parameterized physics models. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_1909_12963 |
| institution | arXiv |
| publishDate | 2019 |
| record_format | arxiv |
| spellingShingle | Machine Learned Hückel Theory: Interfacing Physics and Deep Neural Networks Zubatyuk, Tetiana Nebgen, Ben Lubbers, Nicholas Smith, Justin S. Zubatyuk, Roman Zhou, Guoqing Koh, Christopher Barros, Kipton Isayev, Olexandr Tretiak, Sergei Disordered Systems and Neural Networks Chemical Physics Computational Physics The Hückel Hamiltonian is an incredibly simple tight-binding model famed for its ability to capture qualitative physics phenomena arising from electron interactions in molecules and materials. Part of its simplicity arises from using only two types of empirically fit physics-motivated parameters: the first describes the orbital energies on each atom and the second describes electronic interactions and bonding between atoms. By replacing these traditionally static parameters with dynamically predicted values, we vastly increase the accuracy of the extended Hückel model. The dynamic values are generated with a deep neural network, which is trained to reproduce orbital energies and densities derived from density functional theory. The resulting model retains interpretability while the deep neural network parameterization is smooth, accurate, and reproduces insightful features of the original static parameterization. Finally, we demonstrate that the Hückel model, and not the deep neural network, is responsible for capturing intricate orbital interactions in two molecular case studies. Overall, this work shows the promise of utilizing machine learning to formulate simple, accurate, and dynamically parameterized physics models. |
| title | Machine Learned Hückel Theory: Interfacing Physics and Deep Neural Networks |
| topic | Disordered Systems and Neural Networks Chemical Physics Computational Physics |
| url | https://arxiv.org/abs/1909.12963 |