Structure‐Sensitivity and Electrolyte Effects in CO2 Electroreduction: From Model Studies to Applications

Paula   Sebastián-Pascual; Stefano Mezzavilla; Ifan E. L. Stephens; María Escudero‐Escribano

doi:10.1002/cctc.201900552

Structure‐Sensitivity and Electrolyte Effects in CO₂ Electroreduction: From Model Studies to Applications

Paula Sebastián-Pascual, Stefano Mezzavilla, Ifan E. L. Stephens, María Escudero‐Escribano

Department of Chemistry

23 Citations (Scopus)

Abstract

Aiming to reduce anthropogenic CO₂ emissions, there is an urgent demand to develop more efficient and affordable technologies which convert CO₂ into valuable feedstock molecules. The use of renewable electricity is a promising and sustainable approach to overcome this environmental issue, while producing valuable chemicals and clean fuels. However, the CO₂ electroreduction reaction (CO₂RR) still shows two main gaps: poor selectivity and required large overpotentials make the process not profitable enough. To overcome these challenges, model studies on single-crystalline surfaces aiming to find the relations between surface structure/electrolyte interactions and activity/selectivity are necessary. In these model studies, tuning the electrolyte composition is also key for the fundamental understanding of the CO₂RR. In this review, we first discuss the structure-activity-selectivity relations from studies on well-ordered surfaces, i. e., single crystalline electrodes, for the CO₂RR. We then summarise the role of the electrolyte, presenting work on classical aqueous solvents as well as non-aqueous electrolytes such as ionic liquids. We illustrate the importance of carrying out studies on well-defined electrified interfaces in order to get deep fundamental insights on the mechanism of the CO₂RR, as well as scaling the process for real applications. Ultimately, this knowledge will be essential to rationally design the catalyst with tailored activity and selectivity for CO₂ reduction.

Original language	English
Journal	ChemCatChem
Volume	11
Issue number	16
Pages (from-to)	3626-3645
Number of pages	20
ISSN	1867-3880
DOIs	https://doi.org/10.1002/cctc.201900552
Publication status	Published - 21 Aug 2019

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Cite this

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abstract = "Aiming to reduce anthropogenic CO2 emissions, there is an urgent demand to develop more efficient and affordable technologies which convert CO2 into valuable feedstock molecules. The use of renewable electricity is a promising and sustainable approach to overcome this environmental issue, while producing valuable chemicals and clean fuels. However, the CO2 electroreduction reaction (CO2RR) still shows two main gaps: poor selectivity and required large overpotentials make the process not profitable enough. To overcome these challenges, model studies on single-crystalline surfaces aiming to find the relations between surface structure/electrolyte interactions and activity/selectivity are necessary. In these model studies, tuning the electrolyte composition is also key for the fundamental understanding of the CO2RR. In this review, we first discuss the structure-activity-selectivity relations from studies on well-ordered surfaces, i. e., single crystalline electrodes, for the CO2RR. We then summarise the role of the electrolyte, presenting work on classical aqueous solvents as well as non-aqueous electrolytes such as ionic liquids. We illustrate the importance of carrying out studies on well-defined electrified interfaces in order to get deep fundamental insights on the mechanism of the CO2RR, as well as scaling the process for real applications. Ultimately, this knowledge will be essential to rationally design the catalyst with tailored activity and selectivity for CO2 reduction.",

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AU - Sebastián-Pascual, Paula

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AU - Stephens, Ifan E. L.

AU - Escudero‐Escribano, María

PY - 2019/8/21

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N2 - Aiming to reduce anthropogenic CO2 emissions, there is an urgent demand to develop more efficient and affordable technologies which convert CO2 into valuable feedstock molecules. The use of renewable electricity is a promising and sustainable approach to overcome this environmental issue, while producing valuable chemicals and clean fuels. However, the CO2 electroreduction reaction (CO2RR) still shows two main gaps: poor selectivity and required large overpotentials make the process not profitable enough. To overcome these challenges, model studies on single-crystalline surfaces aiming to find the relations between surface structure/electrolyte interactions and activity/selectivity are necessary. In these model studies, tuning the electrolyte composition is also key for the fundamental understanding of the CO2RR. In this review, we first discuss the structure-activity-selectivity relations from studies on well-ordered surfaces, i. e., single crystalline electrodes, for the CO2RR. We then summarise the role of the electrolyte, presenting work on classical aqueous solvents as well as non-aqueous electrolytes such as ionic liquids. We illustrate the importance of carrying out studies on well-defined electrified interfaces in order to get deep fundamental insights on the mechanism of the CO2RR, as well as scaling the process for real applications. Ultimately, this knowledge will be essential to rationally design the catalyst with tailored activity and selectivity for CO2 reduction.

AB - Aiming to reduce anthropogenic CO2 emissions, there is an urgent demand to develop more efficient and affordable technologies which convert CO2 into valuable feedstock molecules. The use of renewable electricity is a promising and sustainable approach to overcome this environmental issue, while producing valuable chemicals and clean fuels. However, the CO2 electroreduction reaction (CO2RR) still shows two main gaps: poor selectivity and required large overpotentials make the process not profitable enough. To overcome these challenges, model studies on single-crystalline surfaces aiming to find the relations between surface structure/electrolyte interactions and activity/selectivity are necessary. In these model studies, tuning the electrolyte composition is also key for the fundamental understanding of the CO2RR. In this review, we first discuss the structure-activity-selectivity relations from studies on well-ordered surfaces, i. e., single crystalline electrodes, for the CO2RR. We then summarise the role of the electrolyte, presenting work on classical aqueous solvents as well as non-aqueous electrolytes such as ionic liquids. We illustrate the importance of carrying out studies on well-defined electrified interfaces in order to get deep fundamental insights on the mechanism of the CO2RR, as well as scaling the process for real applications. Ultimately, this knowledge will be essential to rationally design the catalyst with tailored activity and selectivity for CO2 reduction.

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