Carbon-Based Electron Buffer Layer on ZnOx−Fe5C2−Fe3O4 Boosts Ethanol Synthesis from CO2 Hydrogenation

Yang Wang; Wenhang Wang; Ruosong He; Meng Li; Jinqiang Zhang; Fengliang Cao; Jianxin Liu; Shiyuan Lin; Xinhua Gao; Guohui Yang; Mingqing Wang; Tao Xing; Tao Liu; Qiang Liu; Han Hu; Noritatsu Tsubaki; Mingbo Wu

doi:10.1002/anie.202311786

Carbon-Based Electron Buffer Layer on ZnO_x−Fe₅C₂−Fe₃O₄ Boosts Ethanol Synthesis from CO₂ Hydrogenation

Yang Wang, Wenhang Wang, Ruosong He, Meng Li, Jinqiang Zhang, Fengliang Cao, Jianxin Liu, Shiyuan Lin, Xinhua Gao, Guohui Yang, Mingqing Wang, Tao Xing, Tao Liu, Qiang Liu, Han Hu, Noritatsu Tsubaki^*, Mingbo Wu^*

^*この論文の責任著者

工学科　応用化学コース

研究成果: ジャーナルへの寄稿 › 学術論文 › 査読

30 被引用数 (Scopus)

抄録

The conversion of CO₂ into ethanol with renewable H₂ has attracted tremendous attention due to its integrated functions of carbon elimination and chemical synthesis, but remains challenging. The electronic properties of a catalyst are essential to determine the adsorption strength and configuration of the key intermediates, therefore altering the reaction network for targeted synthesis. Herein, we describe a catalytic system in which a carbon buffer layer is employed to tailor the electronic properties of the ternary ZnO_x−Fe₅C₂−Fe₃O₄, in which the electron-transfer pathway (ZnO_x→Fe species or carbon layer) ensures the appropriate adsorption strength of −CO* on the catalytic interface, facilitating C−C coupling between −CH_x* and −CO* for ethanol synthesis. Benefiting from this unique electron-transfer buffering effect, an extremely high ethanol yield of 366.6 g_EtOH kg_cat⁻¹ h⁻¹ (with CO of 10 vol % co-feeding) is achieved from CO₂ hydrogenation. This work provides a powerful electronic modulation strategy for catalyst design in terms of highly oriented synthesis.

本文言語	英語
論文番号	e202311786
ジャーナル	Angewandte Chemie - International Edition
巻	62
号	46
DOI	https://doi.org/10.1002/anie.202311786
出版ステータス	出版済み - 2023/11/13

ASJC Scopus 主題領域

触媒
化学一般

UN SDG

この成果は、次の持続可能な開発目標に貢献しています

文献へのアクセス

10.1002/anie.202311786

引用スタイル

Wang, Y., Wang, W., He, R., Li, M., Zhang, J., Cao, F., Liu, J., Lin, S., Gao, X., Yang, G., Wang, M., Xing, T., Liu, T., Liu, Q., Hu, H., Tsubaki, N., & Wu, M. (2023). Carbon-Based Electron Buffer Layer on ZnO_x−Fe₅C₂−Fe₃O₄ Boosts Ethanol Synthesis from CO₂ Hydrogenation. Angewandte Chemie - International Edition, 62(46), 記事 e202311786. https://doi.org/10.1002/anie.202311786

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title = "Carbon-Based Electron Buffer Layer on ZnOx−Fe5C2−Fe3O4 Boosts Ethanol Synthesis from CO2 Hydrogenation",

abstract = "The conversion of CO2 into ethanol with renewable H2 has attracted tremendous attention due to its integrated functions of carbon elimination and chemical synthesis, but remains challenging. The electronic properties of a catalyst are essential to determine the adsorption strength and configuration of the key intermediates, therefore altering the reaction network for targeted synthesis. Herein, we describe a catalytic system in which a carbon buffer layer is employed to tailor the electronic properties of the ternary ZnOx−Fe5C2−Fe3O4, in which the electron-transfer pathway (ZnOx→Fe species or carbon layer) ensures the appropriate adsorption strength of −CO* on the catalytic interface, facilitating C−C coupling between −CHx* and −CO* for ethanol synthesis. Benefiting from this unique electron-transfer buffering effect, an extremely high ethanol yield of 366.6 gEtOH kgcat−1 h−1 (with CO of 10 vol % co-feeding) is achieved from CO2 hydrogenation. This work provides a powerful electronic modulation strategy for catalyst design in terms of highly oriented synthesis.",

keywords = "CO Conversion, Electron Buffer Layer, Ethanol, Fe-Based Catalyst",

author = "Yang Wang and Wenhang Wang and Ruosong He and Meng Li and Jinqiang Zhang and Fengliang Cao and Jianxin Liu and Shiyuan Lin and Xinhua Gao and Guohui Yang and Mingqing Wang and Tao Xing and Tao Liu and Qiang Liu and Han Hu and Noritatsu Tsubaki and Mingbo Wu",

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doi = "10.1002/anie.202311786",

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T1 - Carbon-Based Electron Buffer Layer on ZnOx−Fe5C2−Fe3O4 Boosts Ethanol Synthesis from CO2 Hydrogenation

AU - Wang, Yang

AU - Wang, Wenhang

AU - He, Ruosong

AU - Li, Meng

AU - Zhang, Jinqiang

AU - Cao, Fengliang

AU - Liu, Jianxin

AU - Lin, Shiyuan

AU - Gao, Xinhua

AU - Yang, Guohui

AU - Wang, Mingqing

AU - Xing, Tao

AU - Liu, Tao

AU - Liu, Qiang

AU - Hu, Han

AU - Tsubaki, Noritatsu

AU - Wu, Mingbo

PY - 2023/11/13

Y1 - 2023/11/13

N2 - The conversion of CO2 into ethanol with renewable H2 has attracted tremendous attention due to its integrated functions of carbon elimination and chemical synthesis, but remains challenging. The electronic properties of a catalyst are essential to determine the adsorption strength and configuration of the key intermediates, therefore altering the reaction network for targeted synthesis. Herein, we describe a catalytic system in which a carbon buffer layer is employed to tailor the electronic properties of the ternary ZnOx−Fe5C2−Fe3O4, in which the electron-transfer pathway (ZnOx→Fe species or carbon layer) ensures the appropriate adsorption strength of −CO* on the catalytic interface, facilitating C−C coupling between −CHx* and −CO* for ethanol synthesis. Benefiting from this unique electron-transfer buffering effect, an extremely high ethanol yield of 366.6 gEtOH kgcat−1 h−1 (with CO of 10 vol % co-feeding) is achieved from CO2 hydrogenation. This work provides a powerful electronic modulation strategy for catalyst design in terms of highly oriented synthesis.

AB - The conversion of CO2 into ethanol with renewable H2 has attracted tremendous attention due to its integrated functions of carbon elimination and chemical synthesis, but remains challenging. The electronic properties of a catalyst are essential to determine the adsorption strength and configuration of the key intermediates, therefore altering the reaction network for targeted synthesis. Herein, we describe a catalytic system in which a carbon buffer layer is employed to tailor the electronic properties of the ternary ZnOx−Fe5C2−Fe3O4, in which the electron-transfer pathway (ZnOx→Fe species or carbon layer) ensures the appropriate adsorption strength of −CO* on the catalytic interface, facilitating C−C coupling between −CHx* and −CO* for ethanol synthesis. Benefiting from this unique electron-transfer buffering effect, an extremely high ethanol yield of 366.6 gEtOH kgcat−1 h−1 (with CO of 10 vol % co-feeding) is achieved from CO2 hydrogenation. This work provides a powerful electronic modulation strategy for catalyst design in terms of highly oriented synthesis.

KW - CO Conversion

KW - Electron Buffer Layer

KW - Ethanol

KW - Fe-Based Catalyst

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