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Direct oxidation of methane to methanol using CuMoO 4 .

Wenjian WuWenzhi LiMingwei WuHao ZhangChen ZhuYihang Jiang
Published in: RSC advances (2023)
Upgrading methane into methanol or other high value-added chemicals is not only beneficial to mitigate the greenhouse effect, but also provides basic raw materials for industrial production. Nowadays, most research is limited to zeolite systems, and it is a considerable challenge to extend the support to metal oxides while achieving a high yield of methanol. In this paper, we take advantage of impregnation methods to synthesise a novel Cu/MoO 3 catalyst, which can convert methane to methanol in the gaseous phase. At 600 °C, the Cu(2)/MoO 3 catalyst can achieve a maximum STY CH 3 OH of 47.2 μmol (g -1 h -1 ) with a molar ratio CH 4  : O 2  : H 2 O = 5 : 1.4 : 10. Consequences of SEM, TEM, HRTEM and XRD substantiate that Cu is incorporated into the lattice of MoO 3 to form CuMoO 4 . And transmission infrared spectroscopy, Raman spectroscopy together with XPS characterization techniques confirm the generation of CuMoO 4 , which is the main active site provider. This work provides a new support platform for Cu-based catalyst research in the methane-to-methanol system.
Keyphrases
  • carbon dioxide
  • raman spectroscopy
  • metal organic framework
  • room temperature
  • aqueous solution
  • hydrogen peroxide
  • wastewater treatment
  • nitric oxide
  • ionic liquid
  • life cycle