Data-driven predictions of complex organic mixture permeation in polymer membranes

Young Joo Lee; Lihua Chen; Janhavi Nistane; Hye Youn Jang; Dylan J. Weber; Joseph K. Scott; Neel D. Rangnekar; Bennett D. Marshall; Wenjun Li; J. R. Johnson; Nicholas C. Bruno; M. G. Finn; Rampi Ramprasad; Ryan P. Lively

doi:10.1038/s41467-023-40257-2

Data-driven predictions of complex organic mixture permeation in polymer membranes

Young Joo Lee, Lihua Chen, Janhavi Nistane, Hye Youn Jang, Dylan J. Weber, Joseph K. Scott, Neel D. Rangnekar, Bennett D. Marshall, Wenjun Li, J. R. Johnson, Nicholas C. Bruno, M. G. Finn, Rampi Ramprasad, Ryan P. Lively

Chemical Process Scale Up

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26 Scopus citations

Abstract

Membrane-based organic solvent separations are rapidly emerging as a promising class of technologies for enhancing the energy efficiency of existing separation and purification systems. Polymeric membranes have shown promise in the fractionation or splitting of complex mixtures of organic molecules such as crude oil. Determining the separation performance of a polymer membrane when challenged with a complex mixture has thus far occurred in an ad hoc manner, and methods to predict the performance based on mixture composition and polymer chemistry are unavailable. Here, we combine physics-informed machine learning algorithms (ML) and mass transport simulations to create an integrated predictive model for the separation of complex mixtures containing up to 400 components via any arbitrary linear polymer membrane. We experimentally demonstrate the effectiveness of the model by predicting the separation of two crude oils within 6-7% of the measurements. Integration of ML predictors of diffusion and sorption properties of molecules with transport simulators enables for the rapid screening of polymer membranes prior to physical experimentation for the separation of complex liquid mixtures.

Original language	English
Article number	4931
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-40257-2
State	Published - Dec 2023

Funding

This work was supported by the ExxonMobil Technology and Engineering Company. Y.J.L. acknowledges the fellowship from Kwanjeong Educational Foundation (South Korea). D.J.W. acknowledges U.S. Department of Energy’s Office of Energy Efficiency and Renewable Energy (EERE) under the Advanced Manufacturing Office (award no. DE-EE0007888).

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Lee, Y. J., Chen, L., Nistane, J., Jang, H. Y., Weber, D. J., Scott, J. K., Rangnekar, N. D., Marshall, B. D., Li, W., Johnson, J. R., Bruno, N. C., Finn, M. G., Ramprasad, R., & Lively, R. P. (2023). Data-driven predictions of complex organic mixture permeation in polymer membranes. Nature Communications, 14(1), Article 4931. https://doi.org/10.1038/s41467-023-40257-2

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abstract = "Membrane-based organic solvent separations are rapidly emerging as a promising class of technologies for enhancing the energy efficiency of existing separation and purification systems. Polymeric membranes have shown promise in the fractionation or splitting of complex mixtures of organic molecules such as crude oil. Determining the separation performance of a polymer membrane when challenged with a complex mixture has thus far occurred in an ad hoc manner, and methods to predict the performance based on mixture composition and polymer chemistry are unavailable. Here, we combine physics-informed machine learning algorithms (ML) and mass transport simulations to create an integrated predictive model for the separation of complex mixtures containing up to 400 components via any arbitrary linear polymer membrane. We experimentally demonstrate the effectiveness of the model by predicting the separation of two crude oils within 6-7\% of the measurements. Integration of ML predictors of diffusion and sorption properties of molecules with transport simulators enables for the rapid screening of polymer membranes prior to physical experimentation for the separation of complex liquid mixtures.",

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Data-driven predictions of complex organic mixture permeation in polymer membranes

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