Electrochemical CO2 conversion technologies: state-of-the-art and future perspectives

Electrochemical CO2 conversion technologies: state-of-the-art and future perspectives

Electrochemical reduction of CO2 to produce chemicals or fuels may contribute to the zero-emission goal of the chemical industry. Here, we report the state-of-the-art and future perspective of electrochemical CO2 conversion processes to produce CO, syngas, formic acid and ethylene. We selected and e...

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Veröffentlicht in:Sustainable energy & fuels 2023-11, Vol.7 (23), p.5445-5472
Hauptverfasser: Detz, Remko J, Ferchaud, Claire J, Kalkman, Arie J, Kemper, Jasmin, Sánchez-Martínez, Carlos, Saric, Marija, Shinde, Manoj V
Format: Artikel
Sprache:eng
Schlagworte:
Acid production
Acids
Carbon dioxide
Catalysts
Chemical industry
Chemical reduction
Cost control
Electricity
Electricity distribution
Electrochemistry
Electrolysis
Emissions
Ethylene
Formic acid
Greenhouse gases
High temperature
Learning curves
Low temperature
Maintenance costs
Operating costs
Petrochemicals
Petrochemicals industry
Production costs
Production methods
Route selection
State of the art
Synthesis gas
Technology assessment
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Zusammenfassung:Electrochemical reduction of CO2 to produce chemicals or fuels may contribute to the zero-emission goal of the chemical industry. Here, we report the state-of-the-art and future perspective of electrochemical CO2 conversion processes to produce CO, syngas, formic acid and ethylene. We selected and explored six routes: low-temperature CO production, low-temperature formic acid production, low-temperature ethylene production, high-temperature CO production, high-temperature syngas production, and a tandem approach to produce ethylene. For these routes, we describe the current level of development, performance indicators, and costs. The state-of-the-art of the chlor-alkali process is included as an example of a commercially applied electrochemical process. We calculate the economic performance of the various pathways in terms of levelized production costs and we use a learning curve method to project costs up to 2050. The greenhouse gas performance for all routes is determined and compared to the current reference of production from fossil-based resources. We conclude that high-temperature solid-oxide electrolysis to produce CO and syngas is the most developed and closest to reaching break-even levelized production cost in comparison to the fossil reference. Low-temperature electrolysis processes are at a lower technology readiness level and still need a substantial reduction in investment costs and improvements in process efficiency to achieve break-even with incumbent technology. The most promising of the low-temperature processes is formic acid production. Electrochemical production of formic acid, CO, and syngas results or can soon result in substantial GHG savings compared to their fossil-based alternatives. The extent to which savings can be achieved depends merely on the carbon intensity of the local power grid, or more generally, the supplied electricity. Electrochemical CO2 conversion to produce ethylene would require a very low emission factor of electricity (
ISSN:2398-4902
DOI:10.1039/d3se00775h