Competitive Coordination Constructed Heteronuclear Pt 1 ‐Fe 1 Dual Single‐Atom Sites for Selective Oxidation of Allylic Alcohol

异核分子 烯丙基重排 催化作用 化学 选择性 酒精氧化 组合化学 级联 过渡金属 对偶(语法数字) 电子顺磁共振 异核单量子相干光谱 Atom(片上系统) 苯甲醇 光化学 无机化学 分子 工作(物理) 反应机理 离解(化学) 双重角色 化学物理 环氧化物
作者
Mingyue Zhao,Mengnan Ma,Fanyu Meng,Xin Zhou,Yibin Liu,Xiaobo Chen,Hao Yan,Chaohe Yang,De Chen,Xiang Feng
出处
期刊:Angewandte Chemie [Wiley]
卷期号:65 (1): e20549-e20549 被引量:1
标识
DOI:10.1002/anie.202520549
摘要

Dual single-atom catalysts (DSACs) have attracted considerable attention owing to their exceptional atom efficiency and synergistic catalytic effects. Nevertheless, establishing precise synthetic methodologies for DSACs and exploring its application in complex reaction systems still present significant challenges. Here, we have fabricated a hydroxyapatite (HAP)-supported heteronuclear Pt1-Fe1 dual single-atom catalyst (Pt1-Fe1/HAP) via a competitive coordination strategy for selective oxidation of allylic alcohols. Through a thermodynamically driven competitive coordination process, heteronuclear Pt1-Fe1 with distinct charge densities is co-anchored within adjacent periodic Ca2+ vacancies of HAP lattice via PO4 3- bridges, achieving a controlled atomic separation of ∼2.7 Å for electronic synergy. Unexpectedly, orbital hybridization between heteronuclear Pt1-Fe1 induces a spin-state transition of Fe from low-spin to medium-spin, facilitating activation of O2 and following cascade oxidation of allylic alcohol. Benefiting from the modification of spin state, Pt1-Fe1/HAP exhibits ultrahigh aldehyde selectivity (92%) and a high turnover frequency (12 090.8 h-1) in oxidation of various allylic alcohol substrates, 20-fold higher than that of Pt1/HAP single-atom catalyst (543.8 h-1). This work establishes the thermodynamically driven competitive coordination strategy as a universal approach for constructing high-performance heteronuclear dual-atom catalysts with precisely engineered electronic synergy in demanding industrial processes.
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