再分配(选举)
催化作用
费米能级
望远镜
选择性
化学物理
材料科学
纳米技术
工作职能
工作(物理)
电极
金属
电化学
合理设计
电子结构
化学
非平衡态热力学
物理
原位
数码产品
过渡金属
电荷(物理)
想象
凝聚态物理
水溶液
作者
Kevin M. Siniard,Hailing Yu,Shuai Yuan,Qingju Wang,Xin Wang,Meijia Li,Caiqi Wang,Xiao Tong,Alexander S. Ivanov,Yuanpeng Zhang,Yongqiang Cheng,Murillo Longo Martins,Tao Wang,Felipe Polo‐Garzon,De‐en Jiang,Zili Wu,Zhenzhen Yang,Sheng Dai
标识
DOI:10.1002/anie.202522761
摘要
The metal-support interface is central to governing catalytic transformations. While strong metal-support interaction (SMSI) is an established strategy to tailor the morphology and electronic properties of supported metal catalysts, the role of interfacial charge redistribution in SMSI formation remains poorly understood and rarely leveraged. Here, we report a dual-stimuli approach that combines pH modulation with ultrasonication to mediate SMSI construction in aqueous solution through dynamic Fermi level tuning. By leveraging in situ pH-driven charge redistribution at the metal-support interface, we achieve controllable SMSI encapsulation of metal nanoparticles, as verified by electrochemical analysis, work function measurements, and x-ray-based techniques. The resulting catalysts exhibit tunable SMSI features and deliver enhanced activity and selectivity in hydrogenation reactions. This work establishes a facile strategy to modulate catalyst structure and electronic properties by exploiting Fermi level variation as a driving force, thereby advancing rational SMSI design and catalytic performance across diverse environments.
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