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Methane oxidation to methyl trifluoroacetate by simple anionic palladium catalyst: Comprehensive understanding of K2S2O8-based methane oxidation in CF3CO2H

[Display omitted] •PdCl42- can effectively convert methane to methyl trifluoroacetae in the K2S2O8-CF3CO2H oxidation system.•The anionic catalyst form appears to increase the Pd solubility in the polar protic HTFA solvent.•Pd(CF3CO2)42- is supposed to be the real catalytic species in this PdCl42- -...

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Bibliographic Details
Published in:Journal of catalysis 2022-09, Vol.413, p.803-811
Main Authors: Cheong, Seok-Hyeon, Kim, Daeun, Dang, Huyen Tran, Kim, Dongwook, Seo, Bora, Cheong, Minserk, Hong, Soon Hyeok, Lee, Hyunjoo
Format: Article
Language:English
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Summary:[Display omitted] •PdCl42- can effectively convert methane to methyl trifluoroacetae in the K2S2O8-CF3CO2H oxidation system.•The anionic catalyst form appears to increase the Pd solubility in the polar protic HTFA solvent.•Pd(CF3CO2)42- is supposed to be the real catalytic species in this PdCl42- - catalyzed methane oxidation.•Solvent CF3CO2H oxidation limit the yield of methyl trifluoroacete. The partial oxidation of methane to methyl trifluoroacetate (MeTFA) in trifluoroacetic acid (HTFA) is one of the most selective methane conversion reactions. We report that the simple anionic form of palladium, PdCl42- can effectively convert methane to MeTFA compared to neutral PdCl2 in the K2S2O8-HTFA oxidation system. The anionic catalyst form appears to increase the Pd solubility in the polar protic HTFA solvent, thereby facilitating transformation to PdTFA42- which is supposed to be the real catalytic species in this PdCl42- - catalyzed methane oxidation. It was found that not only methane oxidation but also solvent HTFA oxidation proceeded to a substantial degree, which limited the yield of MeTFA by consuming the oxidant, K2S2O8. Furthermore, for the first time, the role of trifluoroacetic anhydride (TFAA) was identified; it removes water produced by KHSO4 and HF, which are the reduced form of K2S2O8 and the oxidation byproduct of HTFA, respectively. The reaction equations for methane to MeTFA, and HTFA to CO2 in K2S2O8-HTFA system are suggested.
ISSN:0021-9517
1090-2694
DOI:10.1016/j.jcat.2022.07.031