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Catalytic Hydrogenolysis by Atomically Dispersed Iron Sites Embedded in Chemically and Redox Non-innocent N-Doped Carbon.

Zhicheng LuoLi LiVy T NguyenUddhav KanburYuting LiJie ZhangRenfeng NieAbhranil BiswasSergey L Bud'koJin-Su OhLin ZhouWenyu HuangAaron D SadowShu-Hua WangSusannah L ScottLong Qi
Published in: Journal of the American Chemical Society (2024)
Atomically dispersed first-row transition metals embedded in nitrogen-doped carbon materials (M-N-C) show promising performance in catalytic hydrogenation but are less well-studied for reactions with more complex mechanisms, such as hydrogenolysis. Their ability to catalyze selective C-O bond cleavage of oxygenated hydrocarbons such as aryl alcohols and ethers is enhanced with the participation of ligands directly bound to the metal ion as well as longer-range contributions from the support. In this article, we describe how Fe-N-C catalysts with well-defined local structures for the Fe sites catalyze C-O bond hydrogenolysis. The reaction is facilitated by the N-C support. According to spectroscopic analyses, the as-synthesized catalysts contain mostly pentacoordinated Fe III sites, with four in-plane nitrogen donor ligands and one axial hydroxyl ligand. In the presence of 20 bar of H 2 at 170-230 °C, the hydroxyl ligand is lost when N 4 Fe III OH is reduced to N 4 Fe II , assisted by the H 2 chemisorbed on the support. When an alcohol binds to the tetracoordinated Fe II sites, homolytic cleavage of the O-H bond is accompanied by reoxidation to Fe III and H atom transfer to the support. The role of the N-C support in catalytic hydrogenolysis is analogous to the behavior of chemically and redox-non-innocent ligands in molecular catalysts based on first-row transition metal ions and enhances the ability of M-N-Cs to achieve the types of multistep activations of strong bonds needed to upgrade renewable and recycled feedstocks.
Keyphrases
  • transition metal
  • metal organic framework
  • aqueous solution
  • highly efficient
  • electron transfer
  • quantum dots
  • physical activity
  • molecular dynamics
  • risk assessment
  • crystal structure
  • health risk assessment