<p>This study presents a comprehensive data-driven framework for predicting and interpreting CO<sub>2</sub> uptake in metal–organic frameworks (MOFs) using advanced machine learning (ML) and explainable artificial intelligence (XAI) techniques. A curated dataset of 223 experimentally reported MOF samples, characterized by surface area (SA), pore volume (PV), temperature (T), and pressure (P), was used to train four supervised ML models: Artificial Neural Network (ANN), Random Forest (RF), AdaBoost (AdB), and Gradient Boosting (GB). Among the evaluated models, the GB model achieved the highest predictive accuracy, yielding low training errors (<i>MSE</i> = 0.398, <i>RMSE</i> = 0.63, <i>MAE</i> = 0.211, <i>RRMSE</i> = 0.49, <i>R</i><sup><i>2</i></sup> = 0.99) and maintaining strong generalization on the test set with an <i>MSE</i>, <i>RMSE</i>, <i>MAE</i>, <i>RRMSE</i>, <i>R</i><sup><i>2</i></sup> as 3.752, 1.937, 1.041, 1.495 and 0.982. To ensure model transparency, SHapley Additive exPlanations (SHAP) were employed, revealing “P” and “PV” as the most influential features governing CO<sub>2</sub> adsorption, while “T” showed minimal impact. The interpretability analysis also highlighted nonlinear feature interactions and saturation effects associated with surface area and pore characteristics. Finally, a graphical user interface (GUI) was developed using the optimized GB model, enabling real-time CO<sub>2</sub> uptake prediction based on user-defined inputs. This integrated prediction-interpretation-deployment framework provides a practical and scientifically transparent tool for rapid MOF screening, supporting data-driven advancements in carbon capture and sustainable materials design.</p>

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Data-driven explainable artificial intelligence models for predicting CO2 uptake in metal–organic frameworks

  • Mohd Azfar Shaida,
  • Laiba Saleem,
  • Syed Ali Waqas Ahmad,
  • Saad Shamim Ansari,
  • Syed Muhammad Ibrahim

摘要

This study presents a comprehensive data-driven framework for predicting and interpreting CO2 uptake in metal–organic frameworks (MOFs) using advanced machine learning (ML) and explainable artificial intelligence (XAI) techniques. A curated dataset of 223 experimentally reported MOF samples, characterized by surface area (SA), pore volume (PV), temperature (T), and pressure (P), was used to train four supervised ML models: Artificial Neural Network (ANN), Random Forest (RF), AdaBoost (AdB), and Gradient Boosting (GB). Among the evaluated models, the GB model achieved the highest predictive accuracy, yielding low training errors (MSE = 0.398, RMSE = 0.63, MAE = 0.211, RRMSE = 0.49, R2 = 0.99) and maintaining strong generalization on the test set with an MSE, RMSE, MAE, RRMSE, R2 as 3.752, 1.937, 1.041, 1.495 and 0.982. To ensure model transparency, SHapley Additive exPlanations (SHAP) were employed, revealing “P” and “PV” as the most influential features governing CO2 adsorption, while “T” showed minimal impact. The interpretability analysis also highlighted nonlinear feature interactions and saturation effects associated with surface area and pore characteristics. Finally, a graphical user interface (GUI) was developed using the optimized GB model, enabling real-time CO2 uptake prediction based on user-defined inputs. This integrated prediction-interpretation-deployment framework provides a practical and scientifically transparent tool for rapid MOF screening, supporting data-driven advancements in carbon capture and sustainable materials design.