Size-dependent and sensitivity of copper particle in ternary CuZnAl catalyst for syngas to ethanol

Understanding particle size effect of metal on catalysis has great significance in scientific and industrial applications. Herein, CuZnAl catalysts with narrow Cu particle size distribution had been synthesized and investigated for syngas to ethanol. Selectivity toward to C2+OH sharply increased fro...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Environmental, 2023-11, Vol.336, p.122949, Article 122949
Main Authors: Liu, Yongjun, Li, Zhiwen, Luo, Peng, Cui, Nan, Wang, Kejing, Huang, Wei
Format: Article
Language:English
Subjects:
Cu-based catalyst
Ethanol
In-situ DRIFT
Size effects
Syngas
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Summary:Understanding particle size effect of metal on catalysis has great significance in scientific and industrial applications. Herein, CuZnAl catalysts with narrow Cu particle size distribution had been synthesized and investigated for syngas to ethanol. Selectivity toward to C2+OH sharply increased from 8.9% to 60.5% with the increase of Cu size from 11.8 to 38.3 nm, then it slightly increased to 68.6% when further increasing the size to 49.2 nm, which was attributed to the domination of Cu (111) facet and accompanied by the formation of Cu(111)-ZnO interface at larger Cu sizes, thereby weakened hydrogenation activity and facilitated CHx formation. The in-situ DRIFTS experiment revealed that carbon chain growth was processed by the insertion of CO*/CHO* into the CHx* and the coupling of CHx* and CO2 *. These results substantially broaden the understanding the size effect of Cu and provided guidance for design more active Cu-based catalyst for ethanol synthesis. [Display omitted] •CuZnAl catalysts with various Cu particle sizes were synthesized.•Cu (111) facet and Cu(111)-ZnO interface dominated in larger Cu sizes.•Larger Cu size weakened hydrogenation activity and facilitated CHx formation.•Three routes of carbon chain growth mechanism were proposed.•It provided guidance for designing Cu-based catalysts with high selectivity.
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2023.122949