Radiation-Powered Catalytic Alchemy: 3e– Reduction of Perrhenate via Confined Active Sites in Covalent Organic Framework Nanoreactors

化学 过氯酸盐 催化作用 纳米反应器 共价键 无机化学 还原(数学) 光化学 有机化学 几何学 数学
作者
Yue Wang,Weiyi Wang,Haoyu Peng,Yiqian Wu,Chengguang Yang,Yicheng Wang,Jing Peng,Jiuqiang Li,Zhifang Chai,Li‐Yong Yuan,Maolin Zhai,Wei‐Qun Shi,Maolin Zhai,Weiqun Shi
出处
期刊:Journal of the American Chemical Society [American Chemical Society]
卷期号:147 (35): 32015-32027 被引量:2
标识
DOI:10.1021/jacs.5c09962
摘要

The catalytic reduction of high-valent metal oxysalts to their low-valent counterparts represents a pivotal route for environmental remediation and sustainable resource recovery. However, the inherently low redox potentials of certain oxysalts, exemplified by perrhenate (ReO4-), pose a persistent challenge for conventional reduction strategies. Herein, we report a rationally designed π-conjugated olefin-linked covalent organic framework (COF) catalyst, which incorporates isolated transition metal centers (M = Ni or Cu) to facilitate the γ-ray-powered catalytic reduction of ReO4-. Through synergistic spatial confinement and electronic modulation, the catalyst enables near-quantitative selectivity toward ReO2 production via a unique three-electron (3e-) transfer pathway, overcoming the bottleneck of multielectron reduction. The energy efficiency of the reduction reaches up to 42.1 mmol MJ-1. Synergistic experimental and theoretical investigations reveal that radiation-generated hydrated electrons (eaq-) participate in a coordination-electron relay process, involving a critical μ-oxo double-bridged [M-O(O)-Re] intermediate. Remarkably, the conjugated COF demonstrates superior radiation resistance, retaining crystallinity and porosity after prolonged irradiation. This work establishes a new paradigm for harnessing COFs as robust platforms for heterogeneous radiation catalysis, with potential applications in the treatment of redox-recalcitrant pollutants.
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