Assessing C3–C4 alcohol synthesis pathways over a MgAl oxide supported K/MoS2 catalyst via 13C2-ethanol and 13C2-ethylene co-feeds

[Display omitted] •13C2-ethanol and 13C2-ethylene co-feeds over MgAl oxide supported K/MoS2 catalyst.•Preferential enrichment of terminal carbons in C3–C4 linear alcohols.•CO insertion is the primary pathway to higher alcohols.•Conclusive evidence of ethanol self-coupling to 13C4-1-ButOH with 13C2-E...

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Published in:Journal of molecular catalysis. A, Chemical Chemical, 2016-11, Vol.423 (C), p.224-232
Main Authors: Taborga Claure, Micaela, Lee, Li-Chen, Goh, Jin Wai, Gelbaum, Leslie T., Agrawal, Pradeep K., Jones, Christopher W.
Format: Article
Language:English
Subjects:
CO insertion
Ethanol coupling
Higher alcohols
Molybdenum sulfide
Syngas
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Summary:[Display omitted] •13C2-ethanol and 13C2-ethylene co-feeds over MgAl oxide supported K/MoS2 catalyst.•Preferential enrichment of terminal carbons in C3–C4 linear alcohols.•CO insertion is the primary pathway to higher alcohols.•Conclusive evidence of ethanol self-coupling to 13C4-1-ButOH with 13C2-EtOH co-feed. Mechanisms of C3–C4 alcohol synthesis from syngas are elucidated over a Mg/Al mixed metal oxide (MMO) supported K/MoS2 catalyst via 13C2-ethanol and 13C2-ethylene co-feeds. K/bulk-MoS2 is used as a control catalyst to provide insight into the role of K/MoS2 and K/MoS2-MMO sites on higher alcohol formation pathways. Analysis of the products via 13C NMR show preferential enrichment of terminal carbons in C3–C4 alcohols with both co-feeds, suggesting that CO insertion is the primary higher alcohol synthesis pathway, and that olefin carbonylation proceeds through the same pathway as alcohol formation. The observation of 13C4-1-butanol species during the CO hydrogenation reactions with 13C2-ethanol co-feeds provides conclusive evidence of ethanol self-coupling to 1-butanol as a secondary pathway. Additionally, acetate species are shown to be formed via an acyl precursor reacting with an alkoxy anion. Hydrogenation of an acetyl species (CH3CO*) to an ethoxy intermediate (C2H5O*) is shown to be largely irreversible under the reaction conditions employed, as no preferential enrichment is observed for the acetyl group in acetate species. Propionate species are shown to be formed via esterification of propionate with the corresponding alcohol, while isobutyl alcohol formation observed over both the K/bulk-MoS2 and the MMO supported catalysts occurs via methanol coupling with 1-propanol or 1-propanol derived species.
ISSN:1381-1169
1873-314X
DOI:10.1016/j.molcata.2016.06.025