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Electronic coupling in bifunctional Pd–CoOx interfaces drives reactive oxygen activation for acetone low-temperature oxidation

  • Yani Wu
  • , Jicheng Liu
  • , Jiamei Liu
  • , Zeyu Jiang*
  • , Mingjiao Tian
  • , Jingjing Wang
  • , Fan Dang
  • , Chunli Ai
  • , Reem Albilali
  • , Chi He*
  • *Corresponding author for this work
  • Xi'an Jiaotong University
  • University of Chinese Academy of Sciences

Research output: Contribution to journalArticlepeer-review

Abstract

Integrating transition-metal oxides into noble-metal catalysts has proven effective in enhancing catalytic performance. However, oxygenated volatile organic compounds (OVOCs) purification over bimetallic catalysts is still limited by weak coupling and the accumulation of reaction intermediates. Strengthening the interaction in bimetallic sites offers a promising strategy to overcome these limitations, as it can modulate the electronic structure and d-band center of noble-metal species, thereby promoting the activation of OVOCs and ensuring the desired reaction pathways. Herein, bifunctional Pd–CoOx sites were stabilized on rod-like SBA-15, where electronic coupling between Pd2+ and Co2+ enables efficient charge redistribution and promotes molecular oxygen activated to highly reactive oxygen (O). This interfacial synergy directs acetone oxidation via a kinetically favorable pathway of acetone, aldehydes to carboxylates, while promoting rapid decomposition of key intermediates such as CH2O* and C2H4O2, and avoids the formation of C2H2O intermediate. Meanwhile, this oxygen-mediated pathway remains operative under complex reaction atmospheres (H2S and CH3Cl), accounting for the exceptional catalytic stability of PdCoOx/SBA-15. This work offers valuable insights on the development of specific catalysts with functional active sites to synergistically enhance reactants and surface oxygen species activation for efficient OVOCs oxidation.

Original languageEnglish
Article number176790
JournalChemical Engineering Journal
Volume538
DOIs
StatePublished - 15 Jun 2026

Keywords

  • Acetone oxidation
  • Bifunctional sites
  • Electronic modulation
  • Molecular oxygen activation
  • Surface reaction mechanism

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