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Abstract
The Perturbed Chain Polar Statistical Associating Fluid Theory (PCP-SAFT) equation of state (EoS) is widely used to predict fluid-phase thermodynamics, but parameterization of PCP-SAFT for individual molecules is often challenging. We propose a machine learning framework called ML-SAFT for predicting parameters of PCP-SAFT. In order to provide data for training machine learning models, we created the largest dataset of regressed PCP-SAFT parameters in the literature. We then conducted extensive evaluation of several machine learning architectures for predicting PCP-SAFT parameters. We found that our best model provided accurate predictions for a wider range of molecules than existing predictive techniques with 39 \% average absolute deviation (AAD) in vapor pressure predictions and 9 \% AAD in density predictions.
Supplementary materials
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Supplementary Data 1
Description
Extra figures and hyperparameter tables.
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Title
Supplementary Data 2
Description
Code used to produce the results in paper, regressed PCP-SAFT parameters, SMARTS strings used for group contribution identification, scores of predictions from each model, and predicted vapor pressure and density for all molecules in test set.
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