Facile benzene reduction promoted by a synergistically coupled Cu-Co-Ce ternary mixed oxide

Hao Chen; Wenwen Lin; Zihao Zhang; Zhenzhen Yang; Kecheng Jie; Jie Fu; Shi Ze Yang; Sheng Dai

doi:10.1039/d0sc02238a

Facile benzene reduction promoted by a synergistically coupled Cu-Co-Ce ternary mixed oxide

Hao Chen
, Wenwen Lin
, Zihao Zhang
, Zhenzhen Yang
, Kecheng Jie
, Jie Fu
, Shi Ze Yang
, Sheng Dai

Nanomaterials Chemistry Group

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

Hydrogenation of aromatic rings promoted by earth-abundant metal composites under mild conditions is an attractive and challenging subject in the long term. In this work, a simple active site creation and stabilization strategy was employed to obtain a Cu⁺-containing ternary mixed oxide catalyst. Simply by pre-treatment of the ternary metal oxide precursor under a H₂atmosphere, a Cu⁺-derived heterogeneous catalyst was obtained and denoted as Cu₁Co₅Ce₅O_x. The catalyst showed (1) high Cu⁺species content, (2) a uniform distribution of Cu⁺doped into the lattices of CoO_xand CeO₂, (3) formation of CoO_x/CuO_xand CeO₂/CuO_xinterfaces, and (4) a mesoporous structure. These unique properties of Cu₁Co₅Ce₅O_xendow it with pretty high hydrogenation activity for aromatic rings under mild conditions (100 °C with 5 bar H₂), which is much higher than that of the corresponding binary counterparts and even exceeds the performance of commercial noble metal catalysts (e.g.Pd/C). The synergetic effect plays a crucial role in the catalytic procedure with CeO₂functioning as a hydrogen dissociation and transfer medium, Cu⁺hydrogenating the benzene ring and CoO_xstabilizing the unstable Cu⁺species. This will unlock a new opportunity to design highly efficient earth-abundant metal-derived heterogeneous catalystsviainterface interactions.

Original language	English
Pages (from-to)	5766-5771
Number of pages	6
Journal	Chemical Science
Volume	11
Issue number	22
DOIs	https://doi.org/10.1039/d0sc02238a
State	Published - Jun 14 2020

Funding

HC, ZZY, KCJ, and SD were supported by the Division of Chemical Sciences, Geosciences, and Biosciences, Office of Basic Energy Sciences, U.S. Department of Energy. JF was supported by the National Natural Science Foundation of China (No. 21978259 and 21706228), the Zhejiang Provincial Natural Science Foundation of China (No. LR17B060002) and the Fundamental Research Funds for the Central Universities. The STEM characterization used resources of the Center for Functional Nanomaterials, which is a U.S. DOE Office of Science Facility, at Brookhaven National Laboratory under Contract No. DE-SC0012704.

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title = "Facile benzene reduction promoted by a synergistically coupled Cu-Co-Ce ternary mixed oxide",

abstract = "Hydrogenation of aromatic rings promoted by earth-abundant metal composites under mild conditions is an attractive and challenging subject in the long term. In this work, a simple active site creation and stabilization strategy was employed to obtain a Cu+-containing ternary mixed oxide catalyst. Simply by pre-treatment of the ternary metal oxide precursor under a H2atmosphere, a Cu+-derived heterogeneous catalyst was obtained and denoted as Cu1Co5Ce5Ox. The catalyst showed (1) high Cu+species content, (2) a uniform distribution of Cu+doped into the lattices of CoOxand CeO2, (3) formation of CoOx/CuOxand CeO2/CuOxinterfaces, and (4) a mesoporous structure. These unique properties of Cu1Co5Ce5Oxendow it with pretty high hydrogenation activity for aromatic rings under mild conditions (100 °C with 5 bar H2), which is much higher than that of the corresponding binary counterparts and even exceeds the performance of commercial noble metal catalysts (e.g.Pd/C). The synergetic effect plays a crucial role in the catalytic procedure with CeO2functioning as a hydrogen dissociation and transfer medium, Cu+hydrogenating the benzene ring and CoOxstabilizing the unstable Cu+species. This will unlock a new opportunity to design highly efficient earth-abundant metal-derived heterogeneous catalystsviainterface interactions.",

author = "Hao Chen and Wenwen Lin and Zihao Zhang and Zhenzhen Yang and Kecheng Jie and Jie Fu and Yang, \{Shi Ze\} and Sheng Dai",

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T1 - Facile benzene reduction promoted by a synergistically coupled Cu-Co-Ce ternary mixed oxide

AU - Chen, Hao

AU - Lin, Wenwen

AU - Zhang, Zihao

AU - Yang, Zhenzhen

AU - Jie, Kecheng

AU - Fu, Jie

AU - Yang, Shi Ze

AU - Dai, Sheng

PY - 2020/6/14

Y1 - 2020/6/14

N2 - Hydrogenation of aromatic rings promoted by earth-abundant metal composites under mild conditions is an attractive and challenging subject in the long term. In this work, a simple active site creation and stabilization strategy was employed to obtain a Cu+-containing ternary mixed oxide catalyst. Simply by pre-treatment of the ternary metal oxide precursor under a H2atmosphere, a Cu+-derived heterogeneous catalyst was obtained and denoted as Cu1Co5Ce5Ox. The catalyst showed (1) high Cu+species content, (2) a uniform distribution of Cu+doped into the lattices of CoOxand CeO2, (3) formation of CoOx/CuOxand CeO2/CuOxinterfaces, and (4) a mesoporous structure. These unique properties of Cu1Co5Ce5Oxendow it with pretty high hydrogenation activity for aromatic rings under mild conditions (100 °C with 5 bar H2), which is much higher than that of the corresponding binary counterparts and even exceeds the performance of commercial noble metal catalysts (e.g.Pd/C). The synergetic effect plays a crucial role in the catalytic procedure with CeO2functioning as a hydrogen dissociation and transfer medium, Cu+hydrogenating the benzene ring and CoOxstabilizing the unstable Cu+species. This will unlock a new opportunity to design highly efficient earth-abundant metal-derived heterogeneous catalystsviainterface interactions.

AB - Hydrogenation of aromatic rings promoted by earth-abundant metal composites under mild conditions is an attractive and challenging subject in the long term. In this work, a simple active site creation and stabilization strategy was employed to obtain a Cu+-containing ternary mixed oxide catalyst. Simply by pre-treatment of the ternary metal oxide precursor under a H2atmosphere, a Cu+-derived heterogeneous catalyst was obtained and denoted as Cu1Co5Ce5Ox. The catalyst showed (1) high Cu+species content, (2) a uniform distribution of Cu+doped into the lattices of CoOxand CeO2, (3) formation of CoOx/CuOxand CeO2/CuOxinterfaces, and (4) a mesoporous structure. These unique properties of Cu1Co5Ce5Oxendow it with pretty high hydrogenation activity for aromatic rings under mild conditions (100 °C with 5 bar H2), which is much higher than that of the corresponding binary counterparts and even exceeds the performance of commercial noble metal catalysts (e.g.Pd/C). The synergetic effect plays a crucial role in the catalytic procedure with CeO2functioning as a hydrogen dissociation and transfer medium, Cu+hydrogenating the benzene ring and CoOxstabilizing the unstable Cu+species. This will unlock a new opportunity to design highly efficient earth-abundant metal-derived heterogeneous catalystsviainterface interactions.

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DO - 10.1039/d0sc02238a

M3 - Article

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ER -

Facile benzene reduction promoted by a synergistically coupled Cu-Co-Ce ternary mixed oxide

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