Improving selectivity of CO reduction: Via reducing the coordination of critical intermediates

Yifan Li; Yumin Qian; Yujin Ji; Hui Li; Yuanyue Liu

doi:10.1039/c9ta06529f

Improving selectivity of CO reduction: Via reducing the coordination of critical intermediates

Yifan Li, Yumin Qian, Yujin Ji, Hui Li, Yuanyue Liu^*

^*Corresponding author for this work

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

15 Citations (Scopus)

Abstract

Electrochemical reduction of CO to value-added chemicals has attracted great interest. A challenge is to improve the selectivity towards C₂ chemicals and suppress the formation of CH₄ that is less valuable. Here using first-principles calculations, we show that CH₄ formation can be suppressed via reducing the coordination of critical intermediates. This is demonstrated through the example of double metal atoms anchored on carbon nitride (C₂N), which can efficiently catalyze the production of C₂ chemicals, without CH₄. The high selectivity originates from the weakened binding of the ∗CH/∗CH₂ intermediate with the metal atoms due to the reduced coordination, resulting in coupling with neighboring ∗CO and forming a C₂ intermediate that can further transform into C₂ products. Our work provides a new strategy to improve the selectivity of CO reduction and also suggests a promising candidate.

Original language	English
Pages (from-to)	24000-24004
Number of pages	5
Journal	Journal of Materials Chemistry A
Volume	7
Issue number	41
DOIs	https://doi.org/10.1039/c9ta06529f
Publication status	Published - 2019
Externally published	Yes

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title = "Improving selectivity of CO reduction: Via reducing the coordination of critical intermediates",

abstract = "Electrochemical reduction of CO to value-added chemicals has attracted great interest. A challenge is to improve the selectivity towards C2 chemicals and suppress the formation of CH4 that is less valuable. Here using first-principles calculations, we show that CH4 formation can be suppressed via reducing the coordination of critical intermediates. This is demonstrated through the example of double metal atoms anchored on carbon nitride (C2N), which can efficiently catalyze the production of C2 chemicals, without CH4. The high selectivity originates from the weakened binding of the ∗CH/∗CH2 intermediate with the metal atoms due to the reduced coordination, resulting in coupling with neighboring ∗CO and forming a C2 intermediate that can further transform into C2 products. Our work provides a new strategy to improve the selectivity of CO reduction and also suggests a promising candidate.",

author = "Yifan Li and Yumin Qian and Yujin Ji and Hui Li and Yuanyue Liu",

note = "Publisher Copyright: {\textcopyright} 2019 The Royal Society of Chemistry.",

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doi = "10.1039/c9ta06529f",

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T1 - Improving selectivity of CO reduction

T2 - Via reducing the coordination of critical intermediates

AU - Li, Yifan

AU - Qian, Yumin

AU - Ji, Yujin

AU - Li, Hui

AU - Liu, Yuanyue

PY - 2019

Y1 - 2019

N2 - Electrochemical reduction of CO to value-added chemicals has attracted great interest. A challenge is to improve the selectivity towards C2 chemicals and suppress the formation of CH4 that is less valuable. Here using first-principles calculations, we show that CH4 formation can be suppressed via reducing the coordination of critical intermediates. This is demonstrated through the example of double metal atoms anchored on carbon nitride (C2N), which can efficiently catalyze the production of C2 chemicals, without CH4. The high selectivity originates from the weakened binding of the ∗CH/∗CH2 intermediate with the metal atoms due to the reduced coordination, resulting in coupling with neighboring ∗CO and forming a C2 intermediate that can further transform into C2 products. Our work provides a new strategy to improve the selectivity of CO reduction and also suggests a promising candidate.

AB - Electrochemical reduction of CO to value-added chemicals has attracted great interest. A challenge is to improve the selectivity towards C2 chemicals and suppress the formation of CH4 that is less valuable. Here using first-principles calculations, we show that CH4 formation can be suppressed via reducing the coordination of critical intermediates. This is demonstrated through the example of double metal atoms anchored on carbon nitride (C2N), which can efficiently catalyze the production of C2 chemicals, without CH4. The high selectivity originates from the weakened binding of the ∗CH/∗CH2 intermediate with the metal atoms due to the reduced coordination, resulting in coupling with neighboring ∗CO and forming a C2 intermediate that can further transform into C2 products. Our work provides a new strategy to improve the selectivity of CO reduction and also suggests a promising candidate.

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DO - 10.1039/c9ta06529f

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JO - Journal of Materials Chemistry A

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Improving selectivity of CO reduction: Via reducing the coordination of critical intermediates

Abstract

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