催化作用
选择性
热的
解耦(概率)
材料科学
几何形状
偏移量(计算机科学)
曲面(拓扑)
化学物理
纳米技术
曲面重建
电子结构
钯
几何相位
炔烃
金属
润湿
电子效应
固体表面
联轴节(管道)
多相催化
化学
分子物理学
几何造型
化学工程
科技与社会
平版印刷术
光化学
数码产品
物理
作者
Minghang Li,Zhuowei Fu,Qian Luo,Bin Lü,Liwei Zhang,Shipan Liang,Ting Liu,Yong Wang,Shanjun Mao
标识
DOI:10.1038/s41467-026-70568-z
摘要
The entangled electronic and geometric effects in heterogeneous catalysis have long obscured precise attribution of their individual roles. By employing a thermal-induced surface reconstruction strategy to progressively enhance metal-support interactions, we achieve continuous tuning of Pd's electronic and geometric structures. Using alkyne semi-hydrogenation as a prototypical structure-sensitive probe reaction, we demonstrate that despite the linear coupling of electronic and geometric structures during Pd reconstruction, the turnover frequency scales solely with the geometric descriptor W (quantifying Pd particle flattening), while selectivity regulation bifurcates into two distinct regimes: Below a critical W, electron-deficient Pd sites offset geometric constraints, yielding a non-structure-sensitive selectivity plateau; whereas above this threshold, electron-rich surfaces establish unequivocal geometric control. Moreover, surface reconstruction drastically shrinks the electronic-geometric space of Pd sites for over-hydrogenation side reaction. These insights provide a blueprint for metal catalysts regulation in hydrogenation and may open avenues for quantifying electronic-geometric interplay in other structure-sensitive reactions.
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