Reforming and oxidative dehydrogenation of ethane with CO2 as a soft oxidant over bimetallic catalysts

[Display omitted] •CoPt/CeO2, CoMo/CeO2, and NiMo/CeO2 favor the reforming pathway to produce syngas via the C–C bond cleavage.•FeNi/CeO2 shows promising selectivity to the oxidative dehydrogenation pathway to produce ethylene via the C–H bond cleavage.•DFT calculated energy profiles on CoPt/CeO2 an...

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Bibliographic Details
Published in:Journal of catalysis 2016-11, Vol.343, p.168-177
Main Authors: Myint, MyatNoeZin, Yan, Binhang, Wan, Jie, Zhao, Shen, Chen, Jingguang G.
Format: Article
Language:English
Subjects:
Carbon dioxide
Catalysts
CeO2 supports
Ethanol
Ethylene
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Oxidative dehydrogenation
Oxidative stress
Reforming
Synthesis gas
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Summary:[Display omitted] •CoPt/CeO2, CoMo/CeO2, and NiMo/CeO2 favor the reforming pathway to produce syngas via the C–C bond cleavage.•FeNi/CeO2 shows promising selectivity to the oxidative dehydrogenation pathway to produce ethylene via the C–H bond cleavage.•DFT calculated energy profiles on CoPt/CeO2 and FeNi/CeO2 support different reaction pathways. An efficient mitigation of abundantly available CO2 is critical for sustainable environmental impact as well as for novel industrial applications. Using ethane, CO2 can be catalytically converted into a useful feedstock (synthesis gas) and a value-added monomer (ethylene) via the dry reforming pathway through the C–C bond scission and the oxidative dehydrogenation pathway through the C–H bond scission, respectively. Results from the current flow-reactor study show that the precious metal bimetallic CoPt/CeO2 catalyst undergoes the reforming reaction to produce syngas with enhanced activity and stability compared to the parent monometallic catalysts. In order to replace Pt, the activities of non-precious CoMo/CeO2 and NiMo/CeO2 are investigated and the results indicate that NiMo/CeO2 is nearly as active as CoPt/CeO2 for the reforming pathway. Furthermore, FeNi/CeO2 is identified as a promising catalyst for the oxidative dehydrogenation to produce ethylene. Density functional theory (DFT) calculations are performed to further understand the different pathways of the CoPt/CeO2 and FeNi/CeO2 catalysts.
ISSN:0021-9517
1090-2694
DOI:10.1016/j.jcat.2016.02.004