Unifying Mixed Gas Adsorption in Molecular Sieve Membranes and MOFs using Machine Learning

• URL: http://arxiv.org/abs/2406.13389v1
• Date: Wed, 19 Jun 2024 09:30:11 GMT
• Title: Unifying Mixed Gas Adsorption in Molecular Sieve Membranes and MOFs using Machine Learning
• Authors: Subhadeep Dasgupta, Amal R S, Prabal K. Maiti,
• Abstract summary: Recent machine learning models focus on polymers or metal-organic frameworks (MOFs) separately. The difficulty in creating a unified model that can predict the trends in both types of adsorbents is challenging. In this work, we address these problems using feature vectors comprising only the physical properties of the gas mixtures and adsorbents.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Recent machine learning models to accurately obtain gas adsorption isotherms focus on polymers or metal-organic frameworks (MOFs) separately. The difficulty in creating a unified model that can predict the adsorption trends in both types of adsorbents is challenging, owing to the diversity in their chemical structures. Moreover, models trained only on single gas adsorption data are incapable of predicting adsorption isotherms for binary gas mixtures. In this work, we address these problems using feature vectors comprising only the physical properties of the gas mixtures and adsorbents. Our model is trained on adsorption isotherms of both single and binary mixed gases inside carbon molecular sieving membrane (CMSM), together with data available from CoRE MOF database. The trained models are capable of accurately predicting the adsorption trends in both classes of materials, for both pure and binary components. ML architecture designed for one class of material, is not suitable for predicting the other class, even after proper training, signifying that the model must be trained jointly for proper predictions and transferability. The model is used to predict with good accuracy the CO2 uptake inside CALF-20 framework. This work opens up a new avenue for predicting complex adsorption processes for gas mixtures in a wide range of materials.

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