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Selective methane oxidation by molecular iron catalysts in aqueous medium.

Hiroto FujisakiTomoya IshizukaHiroaki KotaniYoshihito ShiotaKazunari YoshizawaTakahiko Kojima
Published in: Nature (2023)
Using natural gas as chemical feedstock requires efficient oxidation of the constituent alkanes-and primarily methane 1,2 . The current industrial process uses steam reforming at high temperatures and pressures 3,4 to generate a gas mixture that is then further converted into products such as methanol. Molecular Pt catalysts 5-7 have also been used to convert methane to methanol 8 , but their selectivity is generally low owing to overoxidation-the initial oxidation products tend to be easier to oxidize than methane itself. Here we show that N-heterocyclic carbene-ligated Fe II complexes with a hydrophobic cavity capture hydrophobic methane substrate from an aqueous solution and, after oxidation by the Fe centre, release a hydrophilic methanol product back into the solution. We find that increasing the size of the hydrophobic cavities enhances this effect, giving a turnover number of 5.0 × 10 2 and a methanol selectivity of 83% during a 3-h methane oxidation reaction. If the transport limitations arising from the processing of methane in an aqueous medium can be overcome, this catch-and-release strategy provides an efficient and selective approach to using naturally abundant alkane resources.
Keyphrases
  • carbon dioxide
  • aqueous solution
  • anaerobic digestion
  • ionic liquid
  • hydrogen peroxide
  • visible light
  • room temperature
  • liquid chromatography