双金属片
可解释性
合理设计
机器学习
人工智能
计算机科学
密度泛函理论
催化作用
数量结构-活动关系
工作(物理)
甲烷
化学
粒子群优化
药物设计
计算复杂性理论
深度学习
吸附
能量(信号处理)
作者
Mingzhang Pan,Tian Zhang,Jiawei Dong,Yubao Xie,Ke Zhong,Wei Guan,Haiqiao Wei,J. Fu,Yaqiong Su
标识
DOI:10.1002/advs.202524394
摘要
Methane's efficient catalytic removal is vital for sustainable development. Bimetallic catalysts, though promising for methane activation, pose a design challenge due to their complex compositional space. This work introduces an integrated framework that combines high-throughput density functional theory (DFT) and interpretable machine learning to accelerate the rational design of catalysts. Computational screening of face-centered-cubic (FCC) bimetallic catalyst surfaces identifies the bond cleavage energies of the first and the second C─H bonds and methyl adsorption energy as a key descriptor governing successive C─H activation and the shift in the rate-determining step (RDS). Through the synergistic interaction of these descriptors, machine learning models can be constructed more effectively, leading to the discovery of a bimetallic catalyst for consecutive C─H bond cleavages that outperforms conventional natural gas engine aftertreatment systems. Based on the computationally derived DFT dataset, four machine learning models were trained using a particle swarm optimisation (PSO) algorithm, from which the optimal model capable of accurately predicting C─H bond energies was selected. This model also further revealed the dominant electronic structural features of the predictive model through SHapley additive interpretability (SHAP) analysis. This work establishes an interpretable, data-driven methodology for designing high-efficiency multicomponent catalysts.
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