双功能
双金属片
合理设计
催化作用
密度泛函理论
活动中心
活动站点
吸附
材料科学
色散(光学)
工作(物理)
双功能催化剂
金属
纳米技术
组合化学
化学
设计要素和原则
化学工程
分子
反应中间体
纳米材料基催化剂
分子动力学
多相催化
氧化还原
电子结构
氧还原反应
反应动力学
材料设计
最大化
计算机科学
作者
Wenwen Li,Yiming Mo,Lingzhi Kang,Caixia Li,Jingnan Zheng,Chenglong Qiu
出处
期刊:ACS Catalysis
[American Chemical Society]
日期:2025-10-11
卷期号:15 (21): 17689-17702
被引量:5
标识
DOI:10.1021/acscatal.5c04004
摘要
Atomically dispersed bimetallic catalysts (ADCs), an emerging class of electrocatalysts, combine the synergistic advantages of dual-metal active sites with the atomic dispersion and high metal utilization efficiency characteristic of single-atom catalysts (SACs). Their unique structural features offer the potential to exceed the catalytic performance of conventional systems but simultaneously pose challenges due to the absence of well-established rational design principles. This paper proposes and validates a structural design strategy, “Active Center Inheritance,” wherein high-performance SACs are transformed into ADCs by retaining the same active center (M–Nx). This approach not only preserves high catalytic activity but also significantly reduces the computational cost associated with density functional theory (DFT) calculations over 13,500 candidate systems, thereby accelerating the discovery of bifunctional electrocatalysts. A total of 17 high-performance oxygen evolution reaction (OER)/oxygen reduction reaction (ORR) bifunctional catalysts were identified through this strategy. This strategy was successfully generalized to three other ADC structural systems with different spatial arrangements. Moreover, a unified descriptor (φ), composed of four key electronic and atomic features, was constructed to effectively correlate the adsorption behaviors of critical reaction intermediates (*OH, *O, and *OOH) across diverse systems. The results reveal that SACs and ADCs can achieve comparable catalytic activity when constructed with the same M–Nx active center, thereby enabling the synergistic optimization of active sites. This work provides a theoretical basis and a rational design framework for the development of efficient multisite electrocatalysts.
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