Nature Communications (Apr 2024)

Direct conversion of methane to aromatics and hydrogen via a heterogeneous trimetallic synergistic catalyst

  • Pengxi Zhu,
  • Wenjuan Bian,
  • Bin Liu,
  • Hao Deng,
  • Lucun Wang,
  • Xiaozhou Huang,
  • Stephanie L. Spence,
  • Feng Lin,
  • Chuancheng Duan,
  • Dong Ding,
  • Pei Dong,
  • Hanping Ding

DOI
https://doi.org/10.1038/s41467-024-47595-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Non-oxidative methane dehydro-aromatization reaction can co-produce hydrogen and benzene effectively on a molybdenum-zeolite based thermochemical catalyst, which is a very promising approach for natural-gas upgrading. However, the low methane conversion and aromatics selectivity and weak durability restrain the realistic application for industry. Here, a mechanism for enhancing catalysis activity on methane activation and carbon-carbon bond coupling has been found to promote conversion and selectivity simultaneously by adding platinum–bismuth alloy cluster to form a trimetallic catalyst on zeolite (Pt-Bi/Mo/ZSM-5). This bimetallic alloy cluster has synergistic interaction with molybdenum: the formed CH3 * from Mo2C on the external surface of zeolite can efficiently move on for C-C coupling on the surface of Pt-Bi particle to produce C2 compounds, which are the key intermediates of oligomerization. This pathway is parallel with the catalysis on Mo inside the cage. This catalyst demonstrated 18.7% methane conversion and 69.4% benzene selectivity at 710 °C. With 95% methane/5% nitrogen feedstock, it exhibited robust stability with slow deactivation rate of 9.3% after 2 h and instant recovery of 98.6% activity after regeneration in hydrogen. The enhanced catalytic activity is strongly associated with synergistic interaction with Mo and ligand effects of alloys by extensive mechanism studies and DFT calculation.