Effective Screening Descriptors of Metal–Organic Framework-Supported Single-Atom Catalysts for Electrochemical CO<sub>2</sub> Reduction Reactions: A Computational Study
Li-Hui Mou, Jiahui Du, Yanbo Li, Jun Jiang, Linjiang Chen
Abstract
Metal–organic framework-supported single-atom catalysts (SACs@MOF) show considerable promise in CO 2 reduction reactions (CO 2 RR). However, efficiently screening and designing optimal catalysts is hindered by the lack of effective descriptors for encoding the complex chemical microenvironments in SAC@MOF systems. Herein, through combining an intuition-guided dimensionality reduction strategy with machine learning (ML), we identified critical descriptors based on atomic features and the SAC’s constrained coordination geometry, which capture the effects of complex chemical microenvironments on electrochemical CO 2 RR activity and selectivity for UiO-66-supported SACs. With these descriptors, accurate ML models were developed to predict the limiting potentials for producing HCOOH, CO, and CH 4 /CH 3 OH on 48 SACs@UiO-66-X (X = H, NH 2, and Br). Moreover, the transferability of the developed descriptors and ML models was demonstrated on 48 additional systems with X = CH 3, OH, and NO 2 . The accuracy of the predicted activity trends for specific SACs combined with different linker groups and the selectivity of the top-performing catalysts were validated through additional DFT calculations. This study provides an effective framework for understanding and modulating chemical microenvironments, enhancing the design and development of MOF-supported SACs for the CO 2 RR.