Recent Advances in Electrochemical CO2‐to‐Multicarbon Conversion: From Fundamentals to Industrialization

The electrochemical CO2 (eCO2)‐to‐multicarbon conversion with higher value is regarded as a potential way to promote the transformation of industrial production and the green balance of carbon cycle. Recently, a series of advances have been achieved in the progress of eCO2‐to‐multicarbon conversion,...

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Veröffentlicht in:	Advanced energy materials 2023-12, Vol.13 (47), p.n/a
Hauptverfasser:	Wang, Changli, Lv, Zunhang, Feng, Xiao, Yang, Wenxiu, Wang, Bo
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Sprache:	eng
Schlagworte:	Carbon cycle Carbon dioxide Catalysts Catalytic converters characterization technologies Coupling coupling mechanisms electrochemical carbon dioxide conversion to multicarbons Industrial development optimizing strategies
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creator	Wang, Changli Lv, Zunhang Feng, Xiao Yang, Wenxiu Wang, Bo
description	The electrochemical CO2 (eCO2)‐to‐multicarbon conversion with higher value is regarded as a potential way to promote the transformation of industrial production and the green balance of carbon cycle. Recently, a series of advances have been achieved in the progress of eCO2‐to‐multicarbon conversion, including the in‐depth exploration of coupling mechanisms, the up‐to‐date development of characterization techniques, and the novel interdisciplinary design strategies of catalysts and electrolytic systems. Therefore, it is essential to systematically overview the eCO2‐to‐multicarbon conversion from fundamentals to industrialization, compensating for the limited and insufficient reviews that have been reported. To fill the aforementioned research gap, this overview is focused on the eCO2‐to‐multicarbon conversion from fundamentals to industrialization. First, the possible catalytic mechanisms for eCO2‐to‐multicarbon conversion are accordingly summarized in the order of eCO2 reduction, small molecule‐coupled eCO2 reduction, and eCO2 tandem conversion. Second, the up‐to‐date in situ characterization technologies assisting the rationalization of coupling mechanisms are presented. Third, the optimizing strategies of catalysts and electrolytic systems are briefly classified for the advance of industrialization process. Finally, challenges and perspectives for the further development of eCO2‐to‐multicarbon conversion are reasonably proposed, aiming to offer insights for the following work in this field. Insight is deepened from fundamentals to industrialization for electrochemical CO2 conversion to higher value‐added multicarbon products, including coupling mechanisms, characterization technologies and optimizing strategies. Potential future challenges, perspectives, and directions are reasonably proposed for the further development of electrochemical CO2‐to‐multicarbon conversion.
doi_str_mv	10.1002/aenm.202302382
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Recently, a series of advances have been achieved in the progress of eCO2‐to‐multicarbon conversion, including the in‐depth exploration of coupling mechanisms, the up‐to‐date development of characterization techniques, and the novel interdisciplinary design strategies of catalysts and electrolytic systems. Therefore, it is essential to systematically overview the eCO2‐to‐multicarbon conversion from fundamentals to industrialization, compensating for the limited and insufficient reviews that have been reported. To fill the aforementioned research gap, this overview is focused on the eCO2‐to‐multicarbon conversion from fundamentals to industrialization. First, the possible catalytic mechanisms for eCO2‐to‐multicarbon conversion are accordingly summarized in the order of eCO2 reduction, small molecule‐coupled eCO2 reduction, and eCO2 tandem conversion. Second, the up‐to‐date in situ characterization technologies assisting the rationalization of coupling mechanisms are presented. Third, the optimizing strategies of catalysts and electrolytic systems are briefly classified for the advance of industrialization process. Finally, challenges and perspectives for the further development of eCO2‐to‐multicarbon conversion are reasonably proposed, aiming to offer insights for the following work in this field. Insight is deepened from fundamentals to industrialization for electrochemical CO2 conversion to higher value‐added multicarbon products, including coupling mechanisms, characterization technologies and optimizing strategies. 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Third, the optimizing strategies of catalysts and electrolytic systems are briefly classified for the advance of industrialization process. Finally, challenges and perspectives for the further development of eCO2‐to‐multicarbon conversion are reasonably proposed, aiming to offer insights for the following work in this field. Insight is deepened from fundamentals to industrialization for electrochemical CO2 conversion to higher value‐added multicarbon products, including coupling mechanisms, characterization technologies and optimizing strategies. 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subjects	Carbon cycle Carbon dioxide Catalysts Catalytic converters characterization technologies Coupling coupling mechanisms electrochemical carbon dioxide conversion to multicarbons Industrial development optimizing strategies
title	Recent Advances in Electrochemical CO2‐to‐Multicarbon Conversion: From Fundamentals to Industrialization
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