Nature Communications (Sep 2024)

Spatial segregation of catalytic sites within Pd doped H-ZSM-5 for fatty acid hydrodeoxygenation to alkanes

  • Shengzhe Ding,
  • Dario Luis Fernandez Ainaga,
  • Min Hu,
  • Boya Qiu,
  • Ushna Khalid,
  • Carmine D’Agostino,
  • Xiaoxia Ou,
  • Ben Spencer,
  • Xiangli Zhong,
  • Yani Peng,
  • Nicole Hondow,
  • Constantinos Theodoropoulos,
  • Yilai Jiao,
  • Christopher M. A. Parlett,
  • Xiaolei Fan

DOI
https://doi.org/10.1038/s41467-024-51925-2
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 12

Abstract

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Abstract Spatial control over features within multifunctional catalysts can unlock efficient one-pot cascade reactions, which are themselves a pathway to aviation biofuels via hydrodeoxygenation. A synthesis strategy that encompasses spatial orthogonality, i.e., one in which different catalytic species are deposited exclusively within discrete locations of a support architecture, is one solution that permits control over potential interactions between different sites and the cascade process. Here, we report a Pd doped hierarchical zeolite, in which Pd nanoparticles are selectively deposited within the mesopores, while acidity is retained solely within the micropores of ZSM-5. This spatial segregation facilitates hydrodeoxygenation while suppressing undesirable decarboxylation and decarbonation, yielding significant enhancements in activity (30.6 vs 3.6 moldodecane molPd −1 h−1) and selectivity (C12:C11 5.2 vs 1.9) relative to a conventionally prepared counterpart (via wet impregnation). Herein, multifunctional material design can realise efficient fatty acid hydrodeoxygenation, thus advancing the field and inspiring future developments in rationalised catalyst design.