Volume 9, Issue 2
An Potential Energy Surface for the $O+O_2$ Reaction Using Neural Network Approach

Wentao Li & Zhigang Sun

J. At. Mol. Sci., 9 (2018), pp. 25-27.

Published online: 2019-01

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  • Abstract

A new potential energy surface (PES) of the $O_3$ system was reported, based on the PESs reported by Dawes et al. and Schinke et al. The PES of $O_3$ reported by Dawes et al. was fitted using least square method based upon accurate high level ab initio points, and has been applied to many dynamics calculations. However, it is computationally slow and need lots of time to obtain the energy points from the PES. At the same time, the threshold of the ab initio points is low as 2.6 eV, relative to the minimum of the PES, which limits its application. On the contrary, the PES reported by Schinke et al. numerically is fast and extends to high energy. In this work, we first calculated the energy points from these two PESs. Then we fitted these energy points using PIP-NN approach. In this way, a revised version of the PES of $O_3$ was constructed and we used it to perform quantum reactive scattering dynamics calculation.

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@Article{JAMS-9-25, author = {Wentao Li and Zhigang Sun}, title = {An Potential Energy Surface for the $O+O_2$ Reaction Using Neural Network Approach}, journal = {Journal of Atomic and Molecular Sciences}, year = {2019}, volume = {9}, number = {2}, pages = {25--27}, abstract = {

A new potential energy surface (PES) of the $O_3$ system was reported, based on the PESs reported by Dawes et al. and Schinke et al. The PES of $O_3$ reported by Dawes et al. was fitted using least square method based upon accurate high level ab initio points, and has been applied to many dynamics calculations. However, it is computationally slow and need lots of time to obtain the energy points from the PES. At the same time, the threshold of the ab initio points is low as 2.6 eV, relative to the minimum of the PES, which limits its application. On the contrary, the PES reported by Schinke et al. numerically is fast and extends to high energy. In this work, we first calculated the energy points from these two PESs. Then we fitted these energy points using PIP-NN approach. In this way, a revised version of the PES of $O_3$ was constructed and we used it to perform quantum reactive scattering dynamics calculation.

}, issn = {2079-7346}, doi = {https://doi.org/10.4208/jams.101518.112818a}, url = {http://global-sci.org/intro/article_detail/jams/12996.html} }
TY - JOUR T1 - An Potential Energy Surface for the $O+O_2$ Reaction Using Neural Network Approach AU - Wentao Li & Zhigang Sun JO - Journal of Atomic and Molecular Sciences VL - 2 SP - 25 EP - 27 PY - 2019 DA - 2019/01 SN - 9 DO - http://doi.org/10.4208/jams.101518.112818a UR - https://global-sci.org/intro/article_detail/jams/12996.html KW - Weak Interaction, Hydrogen Bond, ESIPT, Charge Redistribution. AB -

A new potential energy surface (PES) of the $O_3$ system was reported, based on the PESs reported by Dawes et al. and Schinke et al. The PES of $O_3$ reported by Dawes et al. was fitted using least square method based upon accurate high level ab initio points, and has been applied to many dynamics calculations. However, it is computationally slow and need lots of time to obtain the energy points from the PES. At the same time, the threshold of the ab initio points is low as 2.6 eV, relative to the minimum of the PES, which limits its application. On the contrary, the PES reported by Schinke et al. numerically is fast and extends to high energy. In this work, we first calculated the energy points from these two PESs. Then we fitted these energy points using PIP-NN approach. In this way, a revised version of the PES of $O_3$ was constructed and we used it to perform quantum reactive scattering dynamics calculation.

Wentao Li and Zhigang Sun. (2019). An Potential Energy Surface for the $O+O_2$ Reaction Using Neural Network Approach. Journal of Atomic and Molecular Sciences. 9 (2). 25-27. doi:10.4208/jams.101518.112818a
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