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Manganese-catalysed divergent silylation of alkenes.

Jie DongXiang-Ai YuanZhongfei YanLiying MuJunyang MaChengjian ZhuJin Xie
Published in: Nature chemistry (2020)
Transition-metal-catalysed, redox-neutral dehydrosilylation of alkenes is a long-standing challenge in organic synthesis, with current methods suffering from low selectivity and narrow scope. In this study, we report a general and simple method for the manganese-catalysed dehydrosilylation and hydrosilylation of alkenes, with Mn2(CO)10 as a catalyst precursor, by using a ligand-tuned metalloradical reactivity strategy. This enables versatility and controllable selectivity with a 1:1 ratio of alkenes and silanes, and the synthetic robustness and practicality of this method are demonstrated using complex alkenes and light olefins. The selectivity of the reaction has been studied using density functional theory calculations, showing the use of an iPrPNP ligand to favour dehydrosilylation, while a JackiePhos ligand favours hydrosilylation. The reaction is redox-neutral and atom-economical, exhibits a broad substrate scope and excellent functional group tolerance, and is suitable for various synthetic applications on a gram scale.
Keyphrases
  • density functional theory
  • molecular dynamics
  • transition metal
  • electron transfer
  • structural basis
  • room temperature
  • molecular dynamics simulations
  • highly efficient
  • gram negative
  • ionic liquid