限制
联轴节(管道)
可扩展性
分子
数量结构-活动关系
人工智能
计算机科学
钥匙(锁)
化学
机器学习
分子描述符
能量(信号处理)
电子
化学物理
计算化学
还原(数学)
接口(物质)
生物系统
电子效应
分子识别
电子转移
分子动力学
机制(生物学)
材料科学
特征(语言学)
训练集
纳米技术
支持向量机
物理
监督学习
作者
Haochen Shen,Bin Jiang,Xiaodong Yang,Ningce Zhang,Hao Jiang,Shuxuan Liu,Luoming Kang,Luhong Zhang,Xiaoming Xao,Yongli Sun,Xiaowei Tantai,Guobin Wen,Na Yang,Bohua Ren,S. J. Wang
标识
DOI:10.1002/anie.202525751
摘要
Molecular regulation at organic-metal interfaces is crucial for C─C coupling in CO2 electroreduction, directly influencing the formation of multi-carbon (C2+) products. However, the non-linear interplay of electronic, spatial, and topological molecular descriptors has hindered the establishment of predictive quantitative structure-activity relationships (QSAR), limiting mechanistic insight. Herein, we employed an interpretable machine learning (ML)-QSAR framework to link molecular features with the C─C coupling free energy barrier (ΔG‡) on Cu surfaces, uncovering the dominant role of interfacial "electron-sponge" behavior. Mechanistically, the modifier molecule donates electrons to Cu, which subsequently redistributes them to *CO/*CHO intermediates and the molecule itself, while also directly stabilizing the intermediates. Shapley Additive Explanations (SHAP) analysis identifies key electronic descriptors, including low minimal local electron affinity (LEAmin), narrow HOMO-LUMO gap and elevated HOMO energy. These descriptors govern the electron-sponge mechanism, facilitating the reduction of ΔG‡. As a representative molecule, 3,4-diaminofurazan (DAF), selected from a library of 5,304 graph-theory-derived compounds, incorporates electron-donating and back-donating amino and furan-azole motifs. Experimental validation shows a 1.8-fold increase in C2+ Faradaic efficiency, from 42% to 77%, confirming the QSAR framework's effectiveness. This descriptor-driven approach was further extended to Au and Ag systems, providing a scalable pathway for designing next-generation electrocatalysts.
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