Photothermal CO2 conversion to ethanol through photothermal 
heterojunction-nanosheet arrays

Li, Xiaodong; Li, Li; Chu, Xingyuan; Liu, Xiaohui; Chen, Guangbo; Guo, Quanquan; Zhang, Zhen; Wang, Mingchao; Wang, Shuming; Tahn, Alexander; Sun, Yongfu; Feng, Xinliang

doi:10.1038/s41467-024-49928-0

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Photothermal CO₂ conversion to ethanol through photothermal heterojunction-nanosheet arrays

Li, X., Li, L., Chu, X., Liu, X., Chen, G., Guo, Q., et al. (2024). Photothermal CO₂ conversion to ethanol through photothermal heterojunction-nanosheet arrays. Nature Communications, 15: 5639. doi:10.1038/s41467-024-49928-0.

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Creators:
Li, Xiaodong¹, Author
Li, Li², Author
Chu, Xingyuan², Author
Liu, Xiaohui², Author
Chen, Guangbo², Author
Guo, Quanquan¹, Author
Zhang, Zhen², Author
Wang, Mingchao², Author
Wang, Shuming², Author
Tahn, Alexander², Author
Sun, Yongfu², Author
Feng, Xinliang¹, Author

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1Department of Synthetic Materials and Functional Devices (SMFD), Max Planck Institute of Microstructure Physics, Max Planck Society, ou_3316580
2External Organizations, ou_persistent22

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Abstract: Photothermal CO₂ conversion to ethanol offers a sustainable solution for achieving net-zero carbon management. However, serious carrier recombination and high C-C coupling energy barrier cause poor performance in ethanol generation. Here, we report a Cu/Cu₂Se-Cu₂O heterojunction-nanosheet array, showcasing a good ethanol yield under visible–near-infrared light without external heating. The Z-scheme Cu₂Se-Cu₂O heterostructure provides spatially separated sites for CO₂ reduction and water oxidation with boosted carrier transport efficiency. The microreactors induced by Cu₂Se nanosheets improve the local concentration of intermediates (CH₃* and CO*), thereby promoting C-C coupling process. Photothermal effect of Cu₂Se nanosheets elevates system’s temperature to around 200 °C. Through synergizing electron and heat flows, we achieve an ethanol generation rate of 149.45 µmol g⁻¹ h⁻¹, with an electron selectivity of 48.75% and an apparent quantum yield of 0.286%. Our work can serve as inspiration for developing photothermal catalysts for CO₂ conversion into multi-carbon chemicals using solar energy.

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Dates: Date issued: 2024-07-05

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Identifiers: DOI: 10.1038/s41467-024-49928-0

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Title: Nature Communications

Abbreviation : Nat. Commun.

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Publ. Info: London : Nature Publishing Group

Pages: - Volume / Issue: 15 Sequence Number: 5639 Start / End Page: - Identifier: ISSN: 2041-1723
CoNE: https://pure.mpg.de/cone/journals/resource/2041-1723