Coupling machine learning and theoretical models to compare key properties of biochar in adsorption kinetics rate and maximum adsorption capacity for emerging contaminants.

[Display omitted] • Emerging contaminants (ECs) removal by biochar was modeled by machine learning (ML) • ML and classical adsorption models were coupled to build models. • Ash content of biochar had most critical influences on the adsorption speed of ECs. • Surface structure of biochar played a dominant role in maximum adsorption capacity. • An interactive Biochar-ECs platform was designed for users based on our ML models. Insights into key properties of biochar with a fast adsorption rate and high adsorption capacity are urgent to design biochar as an adsorbent in pollution emergency treatment. Machine learning (ML) incorporating classical theoretical adsorption models was applied to build prediction models for adsorption kinetics rate (i.e., K) and maximum adsorption capacity (i.e., Q m) of emerging contaminants (ECs) on biochar. Results demonstrated that the prediction performance of adaptive boosting algorithm significantly improved after data preprocessing (i.e., log-transformation) in the small unbalanced datasets with R 2 of 0.865 and 0.874 for K and Q m , respectively. The surface chemistry, primarily led by ash content of biochar significantly influenced the K, while surface porous structure of biochar showed a dominant role in predicting Q m. An interactive platform was deployed for relevant scientists to predict K and Q m of new biochar for ECs. The research provided practical references for future engineered biochar design for ECs removal. [ABSTRACT FROM AUTHOR]