Summary
This proposal will develop enhanced electrolysis devices enabling CO2 to be converted into high value chemicals. Specifically this project will improve selectivity, efficiency and durability of electrochemical CO2 conversion into either carbon monoxide, ethanol or ethylene. The immediate focus will be on the highly economically attractive chemicals industry, with the long term goal of using this as a stepping stone towards the fuels industry.
New catalysts, gas diffusion layers, and membranes will all be developed to improve performance in commercially scalable type devices. Single site catalyst will be used to create high selectivity towards carbon monoxide production, whereas a dual catalyst approach will be used to produce ethanol. Variations in morphology and surface structuring will be the key to eliminating side reaction in ethylene production
The greatest novelty of this project will be to use modifications in the reaction environment to effect reaction selectivity. The hydrophobicity and pore size will be varied in the gas diffusion layer and anion exchange membranes and ionomers will be developed to improve performance. The entire device will be comprehensively modeled from the quantum regime all the way to the complete device to relate macroscopic changes with catalytic improvements. Developments in both improved catalysts as well as optimization of reaction environment will allow for high CO2 conversion selectivity, (CO 90%, ethanol 80%, ethylene 90%) at high energy efficiencies (> 40%) and at high rates (> 200 mA/cm2).
A life cycle analysis will focus on electrical power and CO2 inputs as well as the specific products to discover the most effective market opportunities for this technology moving forward. In addition social acceptance issues will be investigated to ensure this technology is developed in a manner that optimizes this aspect as well.
New catalysts, gas diffusion layers, and membranes will all be developed to improve performance in commercially scalable type devices. Single site catalyst will be used to create high selectivity towards carbon monoxide production, whereas a dual catalyst approach will be used to produce ethanol. Variations in morphology and surface structuring will be the key to eliminating side reaction in ethylene production
The greatest novelty of this project will be to use modifications in the reaction environment to effect reaction selectivity. The hydrophobicity and pore size will be varied in the gas diffusion layer and anion exchange membranes and ionomers will be developed to improve performance. The entire device will be comprehensively modeled from the quantum regime all the way to the complete device to relate macroscopic changes with catalytic improvements. Developments in both improved catalysts as well as optimization of reaction environment will allow for high CO2 conversion selectivity, (CO 90%, ethanol 80%, ethylene 90%) at high energy efficiencies (> 40%) and at high rates (> 200 mA/cm2).
A life cycle analysis will focus on electrical power and CO2 inputs as well as the specific products to discover the most effective market opportunities for this technology moving forward. In addition social acceptance issues will be investigated to ensure this technology is developed in a manner that optimizes this aspect as well.
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| Web resources: | https://cordis.europa.eu/project/id/851441 |
| Start date: | 01-01-2020 |
| End date: | 31-03-2023 |
| Total budget - Public funding: | 3 971 832,00 Euro - 3 772 265,00 Euro |
Cordis data
Original description
This proposal will develop enhanced electrolysis devices enabling CO2 to be converted into high value chemicals. Specifically this project will improve selectivity, efficiency and durability of electrochemical CO2 conversion into either carbon monoxide, ethanol or ethylene. The immediate focus will be on the highly economically attractive chemicals industry, with the long term goal of using this as a stepping stone towards the fuels industry.New catalysts, gas diffusion layers, and membranes will all be developed to improve performance in commercially scalable type devices. Single site catalyst will be used to create high selectivity towards carbon monoxide production, whereas a dual catalyst approach will be used to produce ethanol. Variations in morphology and surface structuring will be the key to eliminating side reaction in ethylene production
The greatest novelty of this project will be to use modifications in the reaction environment to effect reaction selectivity. The hydrophobicity and pore size will be varied in the gas diffusion layer and anion exchange membranes and ionomers will be developed to improve performance. The entire device will be comprehensively modeled from the quantum regime all the way to the complete device to relate macroscopic changes with catalytic improvements. Developments in both improved catalysts as well as optimization of reaction environment will allow for high CO2 conversion selectivity, (CO 90%, ethanol 80%, ethylene 90%) at high energy efficiencies (> 40%) and at high rates (> 200 mA/cm2).
A life cycle analysis will focus on electrical power and CO2 inputs as well as the specific products to discover the most effective market opportunities for this technology moving forward. In addition social acceptance issues will be investigated to ensure this technology is developed in a manner that optimizes this aspect as well.
Status
CLOSEDCall topic
LC-SC3-RES-1-2019-2020Update Date
26-10-2022
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Organisations
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| DANMARKS TEKNISKE UNIVERSITET (Coördinator)
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| BOARD OF TRUSTEES OF THE LELAND STANFORD JUNIOR UNIVERSITY
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| ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE (EPFL)
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| INDUSTRIE DE NORA SPA-IDN
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| PRETEXO
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| RINA CONSULTING SPA
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| TECHNISCHE UNIVERSITAT BERLIN
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| TECHNISCHE UNIVERSITEIT DELFT
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| UNIVERSITY OF SURREY