化学
激进的
均分解
催化作用
光化学
氢原子
碳原子
腺苷钴胺
碳纤维
组合化学
反应中间体
二聚体
酶催化
反应机理
自由基取代
催化循环
模块化设计
氢
反应中间体
化学反应
有机化学
化学合成
芳基
β-断裂
均相催化
原子转移自由基聚合
机制(生物学)
降级(电信)
作者
Yì Wáng,Huayan Xu,Xinyue Zhang,Yiting Gu,Fengqian Ma,Shuai Yao,Xingliang Lu,Zia Ul Mustafa,Yidong Wang,Chong Du,Shuqun Zhang,Yangyang Shen
摘要
Carbon radicals are fundamental and pivotal intermediates found in a veritable cornucopia of applications in diverse chemical contexts. Although nature elegantly employs them in enzymes like adenosylcobalamin (AdoCbl) for hydrogen atom transfer catalysis via dynamic cobalt–carbon covalency, their synthetic application in laboratory settings has been stymied by a fundamental paradox: transient radicals form irreversible bonds, while persistent radicals are catalytically inert. Inspired by AdoCbl, we report a catalytic system that circumvents this limitation through the reversible homolysis of a tailored dimer with a dynamic C(sp3)–C(sp3) bond. This mechanism allows the nascent carbon radical to interact reversibly with vinyl cyclopropanes, facilitating subsequent irreversible [3 + 2] reactions with alkenes and the regeneration of active catalyst. The power of this approach is demonstrated in a highly efficient and modular synthesis of cis-cyclopentanes, offering opportunities to rapidly access complex architectures and novel chemical spaces for lead discoveries.
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