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Abstract
The application of machine learning (ML) techniques in materials science has revolutionized the pace and scope of materials research and design. In the case of metal-organic frameworks (MOFs), a promising class of materials due to their tunable properties and versatile applications in gas adsorption and separation, ML has helped survey the vast material space. This study explores the integration of reinforcement learning (RL), specifically Q-learning, with Gaussian processes (GPs) for predictive modeling of adsorption in MOFs. We demonstrate the effectiveness of the RL-driven framework in guiding the selection of training data points and optimizing predictive model performance for methane and carbon dioxide adsorption, using two different reward metrics. Our results highlight the adaptability and versatility of RL in navigating the adsorption predictions in MOFs, with the integration of GPs enhancing the robustness and reliability of predictive modeling.
Supplementary materials
Title
Optimizing the Prediction of Adsorption in Metal-Organic Frameworks Leveraging Q-Learning (SI)
Description
Supporting Information for the Manuscript which includes other key results as directed from the main manuscript.
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