Identifying the Catalytic Descriptor of Single-Atom Catalysts in Nitrate Reduction Reaction: An Interpretable Machine-Learning Method

Abstract

Elucidating the catalytic descriptor that accurately characterizes the structure-activity relationships of typical catalysts for various important heterogeneous catalytic reactions is pivotal for designing high-efficient catalytic systems. Here, an interpretable machine learning technique was employed to identify the key determinants governing the nitrate reduction reaction ( NO3RR) performance across 286 single-atom catalysts (SACs) with the active sites anchored on double-vacancy BC3 monolayers. Through Shapley Additive Explanations (SHAP) analysis with reliable predictive accuracy, we quantitatively demonstrated that, favorable NO3RR activity stems from a delicate balance among three critical factors: low NV, moderate DN, and specific doping patterns. Building upon these insights, we established a descriptor () that integrates the intrinsic catalytic properties and the intermediate O-N-H angle (θ), effectively capturing the underlying structure-activity relationship. Guided by this, we further identified 16 promising catalysts with predicted low limiting potential (U L). Importantly, these catalysts are composed of cost-effective non-precious metal elements and are predicted to surpass most reported catalysts, with the best-performing Ti-V-1N1 is predicted to have an ultra-low U L of -0.10 V.

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