期刊
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
卷 46, 期 28, 页码 14944-14952出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijhydene.2020.07.008
关键词
Molten carbonates; CO formation; Electrochemical mechanism
资金
- MESRI (Ministere de l'enseignement superieur, de la recherche et de l'innovation, France)
- PSL (Paris Sciences et Lettres University)
- [PLANEX ANR-11-EQPX-0-01]
- [ANR MCEC 17-CE05-0025-01]
In order to reduce carbon dioxide emissions, one solution is to convert CO2 into valuable chemicals or fuels through electrochemical reduction, such as transforming it into CO. High temperature electrolysis cells may be the best devices for producing syngas. Research shows that molten carbonates have a significantly higher ability to dissolve CO2 than other solvents, highlighting the need to investigate the mechanism of CO2 reduction for further utilization.
In order to reduce carbon dioxide emission, one solution is to convert into valuable chemicals or fuels, e.g. transforming CO2 into CO by electrochemical reduction. Thus, this greenhouse gas could be re-used in particular as syngas (CO + H2) by co-electrolysis of CO2/ H2O. High temperature electrolysis cells can be the best energetic devices to produce such syngas. In particular, molten carbonates are known to solubilize CO2 very significantly higher than other solvents. Therefore, it is compulsory to investigate and understand the mechanism of CO2 reduction in such media to consider its further use and valorisation. The present study is a critical approach aiming at elucidating the mechanisms for CO2 electroreduction, using an inert Pt electrode in the molten eutectic Li2CO3-K2CO3 (6238 mol%), at 650 ?C, under different partial pressures of CO2. Complementary electrochemical techniques, including sweep square-wave voltammetry and relaxation chronopotentiometry, were carried out. Their combination allowed us to evidence that the electroreduction of CO2 into CO is feasible in oxo-acidic conditions, involving a diffusionlimited quasi reversible system in a one electron-step. ? 2020 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.
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