Selective electrocatalytic synthesis of urea with nitrate and carbon dioxide

Chade Lv; Lixiang Zhong; Hengjie Liu; Zhiwei Fang; Chunshuang Yan; Mengxin Chen; Yi Kong; Carmen Lee; Daobin Liu; Shuzhou Li; Jiawei Liu; Li Song; Gang Chen; Qingyu Yan; Guihua Yu

doi:10.1038/s41893-021-00741-3

Selective electrocatalytic synthesis of urea with nitrate and carbon dioxide

Chade Lv, Lixiang Zhong, Hengjie Liu, Zhiwei Fang, Chunshuang Yan, Mengxin Chen, Yi Kong, Carmen Lee, Daobin Liu, Shuzhou Li^*, Jiawei Liu, Li Song^*, Gang Chen, Qingyu Yan^*, Guihua Yu^*

^*Corresponding author for this work

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

419 Citations (Scopus)

Abstract

Synthetic nitrogen fertilizer such as urea has been key to increasing crop productivity and feeding a growing population. However, the conventional urea production relies on energy-intensive processes, consuming approximately 2% of annual global energy. Here, we report on a more-sustainable electrocatalytic approach that allows for direct and selective synthesis of urea from nitrate and carbon dioxide with an indium hydroxide catalyst at ambient conditions. Remarkably, Faradaic efficiency, nitrogen selectivity and carbon selectivity reach 53.4%, 82.9% and ~100%, respectively. The engineered surface semiconducting behaviour of the catalyst is found to suppress hydrogen evolution reaction. The key step of C–N coupling initiates through the reaction between *NO₂ and *CO₂ intermediates owing to the low energy barrier on {100} facets. This work suggests an appealing route of urea production and provides deep insight into the underlying chemistry of C–N coupling reaction that could guide sustainable synthesis of other indispensable chemicals.

Original language	English
Pages (from-to)	868-876
Number of pages	9
Journal	Nature Sustainability
Volume	4
Issue number	10
DOIs	https://doi.org/10.1038/s41893-021-00741-3
Publication status	Published - Oct 2021
Externally published	Yes

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title = "Selective electrocatalytic synthesis of urea with nitrate and carbon dioxide",

abstract = "Synthetic nitrogen fertilizer such as urea has been key to increasing crop productivity and feeding a growing population. However, the conventional urea production relies on energy-intensive processes, consuming approximately 2% of annual global energy. Here, we report on a more-sustainable electrocatalytic approach that allows for direct and selective synthesis of urea from nitrate and carbon dioxide with an indium hydroxide catalyst at ambient conditions. Remarkably, Faradaic efficiency, nitrogen selectivity and carbon selectivity reach 53.4%, 82.9% and ~100%, respectively. The engineered surface semiconducting behaviour of the catalyst is found to suppress hydrogen evolution reaction. The key step of C–N coupling initiates through the reaction between *NO2 and *CO2 intermediates owing to the low energy barrier on {100} facets. This work suggests an appealing route of urea production and provides deep insight into the underlying chemistry of C–N coupling reaction that could guide sustainable synthesis of other indispensable chemicals.",

author = "Chade Lv and Lixiang Zhong and Hengjie Liu and Zhiwei Fang and Chunshuang Yan and Mengxin Chen and Yi Kong and Carmen Lee and Daobin Liu and Shuzhou Li and Jiawei Liu and Li Song and Gang Chen and Qingyu Yan and Guihua Yu",

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doi = "10.1038/s41893-021-00741-3",

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T1 - Selective electrocatalytic synthesis of urea with nitrate and carbon dioxide

AU - Lv, Chade

AU - Zhong, Lixiang

AU - Liu, Hengjie

AU - Fang, Zhiwei

AU - Yan, Chunshuang

AU - Chen, Mengxin

AU - Kong, Yi

AU - Lee, Carmen

AU - Liu, Daobin

AU - Li, Shuzhou

AU - Liu, Jiawei

AU - Song, Li

AU - Chen, Gang

AU - Yan, Qingyu

AU - Yu, Guihua

PY - 2021/10

Y1 - 2021/10

N2 - Synthetic nitrogen fertilizer such as urea has been key to increasing crop productivity and feeding a growing population. However, the conventional urea production relies on energy-intensive processes, consuming approximately 2% of annual global energy. Here, we report on a more-sustainable electrocatalytic approach that allows for direct and selective synthesis of urea from nitrate and carbon dioxide with an indium hydroxide catalyst at ambient conditions. Remarkably, Faradaic efficiency, nitrogen selectivity and carbon selectivity reach 53.4%, 82.9% and ~100%, respectively. The engineered surface semiconducting behaviour of the catalyst is found to suppress hydrogen evolution reaction. The key step of C–N coupling initiates through the reaction between *NO2 and *CO2 intermediates owing to the low energy barrier on {100} facets. This work suggests an appealing route of urea production and provides deep insight into the underlying chemistry of C–N coupling reaction that could guide sustainable synthesis of other indispensable chemicals.

AB - Synthetic nitrogen fertilizer such as urea has been key to increasing crop productivity and feeding a growing population. However, the conventional urea production relies on energy-intensive processes, consuming approximately 2% of annual global energy. Here, we report on a more-sustainable electrocatalytic approach that allows for direct and selective synthesis of urea from nitrate and carbon dioxide with an indium hydroxide catalyst at ambient conditions. Remarkably, Faradaic efficiency, nitrogen selectivity and carbon selectivity reach 53.4%, 82.9% and ~100%, respectively. The engineered surface semiconducting behaviour of the catalyst is found to suppress hydrogen evolution reaction. The key step of C–N coupling initiates through the reaction between *NO2 and *CO2 intermediates owing to the low energy barrier on {100} facets. This work suggests an appealing route of urea production and provides deep insight into the underlying chemistry of C–N coupling reaction that could guide sustainable synthesis of other indispensable chemicals.

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DO - 10.1038/s41893-021-00741-3

M3 - Article

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SN - 2398-9629

VL - 4

SP - 868

EP - 876

JO - Nature Sustainability

JF - Nature Sustainability

IS - 10

ER -

Selective electrocatalytic synthesis of urea with nitrate and carbon dioxide

Abstract

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