An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets
The reaction coordinate (RC) is the principal collective variable or feature that determines the progress along an activated or reactive process. In a molecular simulation using enhanced sampling, a good description of the RC is crucial for generating sufficient statistics. Moreover, the RC provides...
| Published in: | The Journal of Chemical Physics |
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AIP Publishing
2021
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| Online Access: | http://dx.doi.org/10.1063/5.0058639 https://pubs.aip.org/aip/jcp/article-pdf/doi/10.1063/5.0058639/15965191/064103_1_online.pdf |
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craippubl:10.1063/5.0058639 2024-06-23T07:54:37+00:00 An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets Frassek, M. Arjun, A. Bolhuis, P. G. 2021 http://dx.doi.org/10.1063/5.0058639 https://pubs.aip.org/aip/jcp/article-pdf/doi/10.1063/5.0058639/15965191/064103_1_online.pdf en eng AIP Publishing The Journal of Chemical Physics volume 155, issue 6 ISSN 0021-9606 1089-7690 journal-article 2021 craippubl https://doi.org/10.1063/5.0058639 2024-06-13T04:04:40Z The reaction coordinate (RC) is the principal collective variable or feature that determines the progress along an activated or reactive process. In a molecular simulation using enhanced sampling, a good description of the RC is crucial for generating sufficient statistics. Moreover, the RC provides invaluable atomistic insight into the process under study. The optimal RC is the committor, which represents the likelihood of a system to evolve toward a given state based on the coordinates of all its particles. As the interpretability of such a high dimensional function is low, a more practical approach is to describe the RC by some low-dimensional molecular collective variables or order parameters. While several methods can perform this dimensionality reduction, they usually require a preselection of these low-dimension collective variables (CVs). Here, we propose to automate this dimensionality reduction using an extended autoencoder, which maps the input (many CVs) onto a lower-dimensional latent space, which is subsequently used for the reconstruction of the input as well as the prediction of the committor function. As a consequence, the latent space is optimized for both reconstruction and committor prediction and is likely to yield the best non-linear low-dimensional representation of the committor. We test our extended autoencoder model on simple but nontrivial toy systems, as well as extensive molecular simulation data of methane hydrate nucleation. The extended autoencoder model can effectively extract the underlying mechanism of a reaction, make reliable predictions about the committor of a given configuration, and potentially even generate new paths representative for a reaction. Article in Journal/Newspaper Methane hydrate AIP Publishing The Journal of Chemical Physics 155 6 |
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Open Polar |
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AIP Publishing |
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craippubl |
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English |
| description |
The reaction coordinate (RC) is the principal collective variable or feature that determines the progress along an activated or reactive process. In a molecular simulation using enhanced sampling, a good description of the RC is crucial for generating sufficient statistics. Moreover, the RC provides invaluable atomistic insight into the process under study. The optimal RC is the committor, which represents the likelihood of a system to evolve toward a given state based on the coordinates of all its particles. As the interpretability of such a high dimensional function is low, a more practical approach is to describe the RC by some low-dimensional molecular collective variables or order parameters. While several methods can perform this dimensionality reduction, they usually require a preselection of these low-dimension collective variables (CVs). Here, we propose to automate this dimensionality reduction using an extended autoencoder, which maps the input (many CVs) onto a lower-dimensional latent space, which is subsequently used for the reconstruction of the input as well as the prediction of the committor function. As a consequence, the latent space is optimized for both reconstruction and committor prediction and is likely to yield the best non-linear low-dimensional representation of the committor. We test our extended autoencoder model on simple but nontrivial toy systems, as well as extensive molecular simulation data of methane hydrate nucleation. The extended autoencoder model can effectively extract the underlying mechanism of a reaction, make reliable predictions about the committor of a given configuration, and potentially even generate new paths representative for a reaction. |
| format |
Article in Journal/Newspaper |
| author |
Frassek, M. Arjun, A. Bolhuis, P. G. |
| spellingShingle |
Frassek, M. Arjun, A. Bolhuis, P. G. An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets |
| author_facet |
Frassek, M. Arjun, A. Bolhuis, P. G. |
| author_sort |
Frassek, M. |
| title |
An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets |
| title_short |
An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets |
| title_full |
An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets |
| title_fullStr |
An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets |
| title_full_unstemmed |
An extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets |
| title_sort |
extended autoencoder model for reaction coordinate discovery in rare event molecular dynamics datasets |
| publisher |
AIP Publishing |
| publishDate |
2021 |
| url |
http://dx.doi.org/10.1063/5.0058639 https://pubs.aip.org/aip/jcp/article-pdf/doi/10.1063/5.0058639/15965191/064103_1_online.pdf |
| genre |
Methane hydrate |
| genre_facet |
Methane hydrate |
| op_source |
The Journal of Chemical Physics volume 155, issue 6 ISSN 0021-9606 1089-7690 |
| op_doi |
https://doi.org/10.1063/5.0058639 |
| container_title |
The Journal of Chemical Physics |
| container_volume |
155 |
| container_issue |
6 |
| _version_ |
1802646832740827136 |