Low-Temperature Transformation of Methane to Methanol on Pd1O4 Single Sites Anchored on the Internal Surface of Microporous Silicate

Direct conversion of methane to chemical feedstocks such as methanol under mild conditions is a challenging but ideal solution for utilization of methane. Pd1O4 single‐sites anchored on the internal surface of micropores of a microporous silicate exhibit high selectivity and activity in transforming...

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Bibliographic Details
Published in:Angewandte Chemie (International ed.) 2016-10, Vol.55 (43), p.13441-13445
Main Authors: Huang, Weixin, Zhang, Shiran, Tang, Yu, Li, Yuting, Nguyen, Luan, Li, Yuanyuan, Shan, Junjun, Xiao, Dequan, Gagne, Raphael, Frenkel, Anatoly I., Tao, Franklin (Feng)
Format: Article
Language:English
Subjects:
Catalysts
Chemical industry
Direct conversion
Hydrogen peroxide
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Low temperature
Mathematical analysis
Methane
Methanol
Oxidation
palladium
Phase transitions
Selectivity
single-sites
Temperature effects
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Summary:Direct conversion of methane to chemical feedstocks such as methanol under mild conditions is a challenging but ideal solution for utilization of methane. Pd1O4 single‐sites anchored on the internal surface of micropores of a microporous silicate exhibit high selectivity and activity in transforming CH4 to CH3OH at 50–95 °C in aqueous phase through partial oxidation of CH4 with H2O2. The selectivity for methanol production remains at 86.4 %, while the activity for methanol production at 95 °C is about 2.78 molecules per Pd1O4 site per second when 2.0 wt % CuO is used as a co‐catalyst with the Pd1O4@ZSM‐5. Thermodynamic calculations suggest that the reaction toward methanol production is highly favorable compared to formation of a byproduct, methyl peroxide. Single site Pd1O4 anchored in microspores of zeolite with 2.0 w % CuO is active for transforming of CH4 to CH3OH in aqueous solution in the temperature range of 50–95 °C. Selectivity for production of CH3OH in this temperature range was found to be 78 %‐86 % at 50–95 °C, offering a clear improvement over harsh alternative conditions.
ISSN:1433-7851
1521-3773
DOI:10.1002/anie.201604708