Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis

[Image: see text] Direct electrochemical reduction of CO(2) to C(2) products such as ethylene is more efficient in alkaline media, but it suffers from parasitic loss of reactants due to (bi)carbonate formation. A two-step process where the CO(2) is first electrochemically reduced to CO and subsequen...

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Autores principales: Ramdin, Mahinder, De Mot, Bert, Morrison, Andrew R. T., Breugelmans, Tom, van den Broeke, Leo J. P., Trusler, J. P. Martin, Kortlever, Ruud, de Jong, Wiebren, Moultos, Othonas A., Xiao, Penny, Webley, Paul A., Vlugt, Thijs J. H.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2021
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8679093/
https://www.ncbi.nlm.nih.gov/pubmed/34937989
http://dx.doi.org/10.1021/acs.iecr.1c03592
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author Ramdin, Mahinder
De Mot, Bert
Morrison, Andrew R. T.
Breugelmans, Tom
van den Broeke, Leo J. P.
Trusler, J. P. Martin
Kortlever, Ruud
de Jong, Wiebren
Moultos, Othonas A.
Xiao, Penny
Webley, Paul A.
Vlugt, Thijs J. H.
author_facet Ramdin, Mahinder
De Mot, Bert
Morrison, Andrew R. T.
Breugelmans, Tom
van den Broeke, Leo J. P.
Trusler, J. P. Martin
Kortlever, Ruud
de Jong, Wiebren
Moultos, Othonas A.
Xiao, Penny
Webley, Paul A.
Vlugt, Thijs J. H.
author_sort Ramdin, Mahinder
collection PubMed
description [Image: see text] Direct electrochemical reduction of CO(2) to C(2) products such as ethylene is more efficient in alkaline media, but it suffers from parasitic loss of reactants due to (bi)carbonate formation. A two-step process where the CO(2) is first electrochemically reduced to CO and subsequently converted to desired C(2) products has the potential to overcome the limitations posed by direct CO(2) electroreduction. In this study, we investigated the technical and economic feasibility of the direct and indirect CO(2) conversion routes to C(2) products. For the indirect route, CO(2) to CO conversion in a high temperature solid oxide electrolysis cell (SOEC) or a low temperature electrolyzer has been considered. The product distribution, conversion, selectivities, current densities, and cell potentials are different for both CO(2) conversion routes, which affects the downstream processing and the economics. A detailed process design and techno-economic analysis of both CO(2) conversion pathways are presented, which includes CO(2) capture, CO(2) (and CO) conversion, CO(2) (and CO) recycling, and product separation. Our economic analysis shows that both conversion routes are not profitable under the base case scenario, but the economics can be improved significantly by reducing the cell voltage, the capital cost of the electrolyzers, and the electricity price. For both routes, a cell voltage of 2.5 V, a capital cost of $10,000/m(2), and an electricity price of <$20/MWh will yield a positive net present value and payback times of less than 15 years. Overall, the high temperature (SOEC-based) two-step conversion process has a greater potential for scale-up than the direct electrochemical conversion route. Strategies for integrating the electrochemical CO(2)/CO conversion process into the existing gas and oil infrastructure are outlined. Current barriers for industrialization of CO(2) electrolyzers and possible solutions are discussed as well.
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spelling pubmed-86790932021-12-20 Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis Ramdin, Mahinder De Mot, Bert Morrison, Andrew R. T. Breugelmans, Tom van den Broeke, Leo J. P. Trusler, J. P. Martin Kortlever, Ruud de Jong, Wiebren Moultos, Othonas A. Xiao, Penny Webley, Paul A. Vlugt, Thijs J. H. Ind Eng Chem Res [Image: see text] Direct electrochemical reduction of CO(2) to C(2) products such as ethylene is more efficient in alkaline media, but it suffers from parasitic loss of reactants due to (bi)carbonate formation. A two-step process where the CO(2) is first electrochemically reduced to CO and subsequently converted to desired C(2) products has the potential to overcome the limitations posed by direct CO(2) electroreduction. In this study, we investigated the technical and economic feasibility of the direct and indirect CO(2) conversion routes to C(2) products. For the indirect route, CO(2) to CO conversion in a high temperature solid oxide electrolysis cell (SOEC) or a low temperature electrolyzer has been considered. The product distribution, conversion, selectivities, current densities, and cell potentials are different for both CO(2) conversion routes, which affects the downstream processing and the economics. A detailed process design and techno-economic analysis of both CO(2) conversion pathways are presented, which includes CO(2) capture, CO(2) (and CO) conversion, CO(2) (and CO) recycling, and product separation. Our economic analysis shows that both conversion routes are not profitable under the base case scenario, but the economics can be improved significantly by reducing the cell voltage, the capital cost of the electrolyzers, and the electricity price. For both routes, a cell voltage of 2.5 V, a capital cost of $10,000/m(2), and an electricity price of <$20/MWh will yield a positive net present value and payback times of less than 15 years. Overall, the high temperature (SOEC-based) two-step conversion process has a greater potential for scale-up than the direct electrochemical conversion route. Strategies for integrating the electrochemical CO(2)/CO conversion process into the existing gas and oil infrastructure are outlined. Current barriers for industrialization of CO(2) electrolyzers and possible solutions are discussed as well. American Chemical Society 2021-11-30 2021-12-15 /pmc/articles/PMC8679093/ /pubmed/34937989 http://dx.doi.org/10.1021/acs.iecr.1c03592 Text en © 2021 The Authors. Published by American Chemical Society https://creativecommons.org/licenses/by-nc-nd/4.0/Permits non-commercial access and re-use, provided that author attribution and integrity are maintained; but does not permit creation of adaptations or other derivative works (https://creativecommons.org/licenses/by-nc-nd/4.0/).
spellingShingle Ramdin, Mahinder
De Mot, Bert
Morrison, Andrew R. T.
Breugelmans, Tom
van den Broeke, Leo J. P.
Trusler, J. P. Martin
Kortlever, Ruud
de Jong, Wiebren
Moultos, Othonas A.
Xiao, Penny
Webley, Paul A.
Vlugt, Thijs J. H.
Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis
title Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis
title_full Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis
title_fullStr Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis
title_full_unstemmed Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis
title_short Electroreduction of CO(2)/CO to C(2) Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis
title_sort electroreduction of co(2)/co to c(2) products: process modeling, downstream separation, system integration, and economic analysis
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8679093/
https://www.ncbi.nlm.nih.gov/pubmed/34937989
http://dx.doi.org/10.1021/acs.iecr.1c03592
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