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Autores principales: Ruth, Perrin E., Dufour-Decieux, Vincent, Moakler, Christopher, Cameron, Maria
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2409.19141
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author Ruth, Perrin E.
Dufour-Decieux, Vincent
Moakler, Christopher
Cameron, Maria
author_facet Ruth, Perrin E.
Dufour-Decieux, Vincent
Moakler, Christopher
Cameron, Maria
contents Hydrocarbon pyrolysis is a complex chemical reaction system at extreme temperature and pressure conditions involving large numbers of chemical reactions and chemical species. Only two kinds of atoms are involved: carbons and hydrogens. Its effective description and predictions for new settings are challenging due to the complexity of the system and the high computational cost of generating data by molecular dynamics simulations. On the other hand, the ensemble of molecules present at any moment and the carbon skeletons of these molecules can be viewed as random graphs. Therefore, an adequate random graph model can predict molecular composition at a low computational cost. We propose a random graph model featuring disjoint loops and assortativity correction and a method for learning input distributions from molecular dynamics data. The model uses works of Karrer and Newman (2010) and Newman (2002) as building blocks. We demonstrate that the proposed model accurately predicts the size distribution for small molecules as well as the size distribution of the largest molecule in reaction systems at the pressure of 40.5 GPa, temperature range of 3200K-5000K, and H/C ratio range from 2.25 as in octane through 4 as in methane.
format Preprint
id arxiv_https___arxiv_org_abs_2409_19141
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Cyclic random graph models predicting giant molecules in hydrocarbon pyrolysis
Ruth, Perrin E.
Dufour-Decieux, Vincent
Moakler, Christopher
Cameron, Maria
Chemical Physics
High Energy Physics - Theory
Mathematical Physics
05C92, 92E10
Hydrocarbon pyrolysis is a complex chemical reaction system at extreme temperature and pressure conditions involving large numbers of chemical reactions and chemical species. Only two kinds of atoms are involved: carbons and hydrogens. Its effective description and predictions for new settings are challenging due to the complexity of the system and the high computational cost of generating data by molecular dynamics simulations. On the other hand, the ensemble of molecules present at any moment and the carbon skeletons of these molecules can be viewed as random graphs. Therefore, an adequate random graph model can predict molecular composition at a low computational cost. We propose a random graph model featuring disjoint loops and assortativity correction and a method for learning input distributions from molecular dynamics data. The model uses works of Karrer and Newman (2010) and Newman (2002) as building blocks. We demonstrate that the proposed model accurately predicts the size distribution for small molecules as well as the size distribution of the largest molecule in reaction systems at the pressure of 40.5 GPa, temperature range of 3200K-5000K, and H/C ratio range from 2.25 as in octane through 4 as in methane.
title Cyclic random graph models predicting giant molecules in hydrocarbon pyrolysis
topic Chemical Physics
High Energy Physics - Theory
Mathematical Physics
05C92, 92E10
url https://arxiv.org/abs/2409.19141