Insights into the interfacial structure of Cu/ZrO2 catalysts for methanol synthesis from CO2 hydrogenation: Effects of Cu-supported nano-ZrO2 inverse interface

Insights into the interfacial structure of Cu/ZrO2 catalysts for methanol synthesis from CO2 hydrogenation: Effects of Cu-supported nano-ZrO2 inverse interface

•Cu-support ZrO2 inverse catalysts exhibit higher STYMeOH from CO2 hydrogenation.•The oxide-metal inverse interface is a more MeOH selective structure.•There exists an optimal coverage of nano-ZrO2 on the Cu/ZrO2 inverse catalyst.•The inverse interface favors conversion of key intermediates of forma...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Vol. 470; p. 144006
Main Authors: Xu, Yangzhi, Wang, Maolin, Xie, Zhiwei, Tian, Dong, Sheng, Guan, Tang, Xin, Li, Haibo, Wu, Yichao, Song, Chuqiao, Gao, Xiaofeng, Yao, Siyu, Ma, Ding, Lin, Lili
Format: Journal Article
Language:English
Published: Elsevier B.V 15-08-2023
Subjects:
CO2 hydrogenation
Cu-supported inverse catalysts
Interfacial structure
Methanol
Reaction mechanism
ZrO2-supported catalysts
ZrO2-supported catalysts
Reaction mechanism
Interfacial structure
CO2 hydrogenation
Cu-supported inverse catalysts
Methanol
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Summary:•Cu-support ZrO2 inverse catalysts exhibit higher STYMeOH from CO2 hydrogenation.•The oxide-metal inverse interface is a more MeOH selective structure.•There exists an optimal coverage of nano-ZrO2 on the Cu/ZrO2 inverse catalyst.•The inverse interface favors conversion of key intermediates of formate to methoxy.•Methanol desorbs more easily on inverse catalysts than the conventional ones. The performance of Cu-based catalysts in the low temperature CO2 conversion to methanol highly correlates with interfacial structure. In this paper, the interfacial structure of Cu/ZrO2 catalysts is tuned by changing the molar ratio and precipitation sequence of Cu and Zr precursors in the oxalate precipitation method. Structural characterizations demonstrate that the interface structure gradually transforms from the conventional ZrO2-supported nano-Cu interface to the Cu-supported nano-ZrO2 inverse interface with the ascending Cu/Zr ratio. The space–time yield (STY) of methanol over 90 molCu% Cu/ZrO2 inverse catalyst is 518 gCH3OH/kgcat/h, which far exceeds that of the optimized 40 molCu% Cu/ZrO2 catalyst (351 gCH3OH/kgcat/h). The inverse catalyst also exhibits the best methanol selectivity and lowest apparent activation energy. The correlation of the exposed Cu surface area, Cu particle size, and CO2 adsorption capacity with STYmethanol reveal that there is an optimal coverage of fine ZrO2 particles and the Cu supported nano-ZrO2 inverse configuration is a more suitable structure for methanol synthesis from CO2. High-pressure in situ DRIFTS experiment shows that the adsorbed formate and methoxy intermediates over 90 molCu% Cu/ZrO2 inverse catalyst are more reactive for further hydrogenation. In addition, the inverse configuration is more favorable for the methanol desorption from surface. The enhanced hydrogenation ability and relatively weak oxygenates adsorption of Cu-supported nano-ZrO2 interface is probably the main reasons for the improved catalytic performances of inverse catalysts.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2023.144006