密度泛函理论
电合成
电子转移
解耦(概率)
材料科学
催化作用
电化学
化学
选择性
化学空间
电催化剂
过渡金属
计算机科学
化学物理
吸附
多相催化
联轴节(管道)
纳米技术
混合功能
碳纤维
反应机理
离解(化学)
可扩展性
石墨烯
热化学
费米能级
降维
计算化学
作者
Yun Han,Qingchao Fang,Qilong Wu,Hanqing Yin,M. T. Nasir,Xin Mao,Qin Li,Xiangdong Yao,Aijun Du
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-04-21
卷期号:20 (17): 13363-13372
标识
DOI:10.1021/acsnano.6c04319
摘要
Direct electrosynthesis of urea is highly desirable but is severely hindered by intricate proton-coupled electron transfer networks and competing reduction side reactions. Herein, we present a closed-loop data-driven strategy integrating high-throughput density functional theory and machine learning (ML) to systematically design edge-anchored dual-atom carbon-based catalysts. By decoding the reaction networks of 90 heteroatomic metal pairs, we demonstrate that conventional single-molecule adsorption descriptors fail under coadsorption conditions. Instead, the coadsorption energy (Eads(*CO_NO)) emerges as a robust universal descriptor (R2 = 0.72–0.91). Based on this, a quantitative selectivity phase diagram was constructed, identifying a narrow thermodynamic window (−3.57 to −3.08 eV) that favors the C–N coupling pathway against competitive CO reduction reaction and nitrogen reduction reaction. Leveraging an XGBoost regression model trained on intrinsic atomic features, we rapidly screened a chemical space of 1458 candidates. This workflow successfully narrowed the field to identify Zr_Pd@A and Zn_Pd@Z as superior catalysts, exhibiting completely downhill thermodynamic pathways. Electronic structure analysis reveals that the high d-electron density of Pd near the Fermi level optimally activates NO, while the completely empty or fully occupied d-orbitals of early (Zr) and late (Zn) transition metals weakly bind CO, preventing its deep reduction. This work establishes a scalable ML-assisted paradigm for decoupling competitive mechanisms in complex electrocatalysis.
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