Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation
Energy-efficient capture technologies need to be deployed by 2050 to abate global warming caused by excessive carbon dioxide (CO2) emissions. CO2 capture using alkaline solutions and absorbent regeneration mediated through bipolar membrane electrodialysis (BMED) have been tested previously as a standalone technology. However, the continuous operation of an integrated system remains largely unclear. Here, a bench-scale study was conducted using an integrated prototype to analyze the performance of CO2 capture and electrochemical regeneration using potassium hydroxide (KOH) aqueous solution. A wide range of current densities from 150 to 1000 A/m2 was applied to demonstrate the continuous operation of the CO2 capture system emphasizing the stability in attainable high rich carbon loading and CO2 desorption. The electrochemical regeneration module achieved CO2 desorption efficiency of 70% and absorbent recovery up to 89% under industrial relevant current densities of 500–1000 A/m2. The absorbent recovery has been identified to be a result of the combined effect of load ratio and rich carbon loading. The observed inefficient CO2 separation indicates significant potential to enhance energy efficiency. These results represent a pivotal step forward in electrochemically mediated CO2 capture technology, with promising potential for rapid industrial scale-up in the near future.
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| Format: | Article/Letter to editor biblioteca |
| Language: | English |
| Subjects: | Bipolar membrane electrodialysis, Carbon capture, Electrochemical pH swing, Integration, Post-combustion, Regeneration, Scale-up, |
| Online Access: | https://research.wur.nl/en/publications/carbon-capture-via-electrochemically-mediated-alkaline-absorption |
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dig-wur-nl-wurpubs-6352032024-12-04 Shi, Meng Vallejo Castaño, Sara Shu, Qingdian Tedesco, Michele Kuntke, Philipp Hamelers, Hubertus V.M. Loldrup Fosbøl, Philip Article/Letter to editor Journal of Cleaner Production 476 (2024) ISSN: 0959-6526 Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation 2024 Energy-efficient capture technologies need to be deployed by 2050 to abate global warming caused by excessive carbon dioxide (CO2) emissions. CO2 capture using alkaline solutions and absorbent regeneration mediated through bipolar membrane electrodialysis (BMED) have been tested previously as a standalone technology. However, the continuous operation of an integrated system remains largely unclear. Here, a bench-scale study was conducted using an integrated prototype to analyze the performance of CO2 capture and electrochemical regeneration using potassium hydroxide (KOH) aqueous solution. A wide range of current densities from 150 to 1000 A/m2 was applied to demonstrate the continuous operation of the CO2 capture system emphasizing the stability in attainable high rich carbon loading and CO2 desorption. The electrochemical regeneration module achieved CO2 desorption efficiency of 70% and absorbent recovery up to 89% under industrial relevant current densities of 500–1000 A/m2. The absorbent recovery has been identified to be a result of the combined effect of load ratio and rich carbon loading. The observed inefficient CO2 separation indicates significant potential to enhance energy efficiency. These results represent a pivotal step forward in electrochemically mediated CO2 capture technology, with promising potential for rapid industrial scale-up in the near future. en application/pdf https://research.wur.nl/en/publications/carbon-capture-via-electrochemically-mediated-alkaline-absorption 10.1016/j.jclepro.2024.143767 https://edepot.wur.nl/675110 Bipolar membrane electrodialysis Carbon capture Electrochemical pH swing Integration Post-combustion Regeneration Scale-up https://creativecommons.org/licenses/by/4.0/ https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research |
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Bipolar membrane electrodialysis Carbon capture Electrochemical pH swing Integration Post-combustion Regeneration Scale-up Bipolar membrane electrodialysis Carbon capture Electrochemical pH swing Integration Post-combustion Regeneration Scale-up |
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Bipolar membrane electrodialysis Carbon capture Electrochemical pH swing Integration Post-combustion Regeneration Scale-up Bipolar membrane electrodialysis Carbon capture Electrochemical pH swing Integration Post-combustion Regeneration Scale-up Shi, Meng Vallejo Castaño, Sara Shu, Qingdian Tedesco, Michele Kuntke, Philipp Hamelers, Hubertus V.M. Loldrup Fosbøl, Philip Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation |
| description |
Energy-efficient capture technologies need to be deployed by 2050 to abate global warming caused by excessive carbon dioxide (CO2) emissions. CO2 capture using alkaline solutions and absorbent regeneration mediated through bipolar membrane electrodialysis (BMED) have been tested previously as a standalone technology. However, the continuous operation of an integrated system remains largely unclear. Here, a bench-scale study was conducted using an integrated prototype to analyze the performance of CO2 capture and electrochemical regeneration using potassium hydroxide (KOH) aqueous solution. A wide range of current densities from 150 to 1000 A/m2 was applied to demonstrate the continuous operation of the CO2 capture system emphasizing the stability in attainable high rich carbon loading and CO2 desorption. The electrochemical regeneration module achieved CO2 desorption efficiency of 70% and absorbent recovery up to 89% under industrial relevant current densities of 500–1000 A/m2. The absorbent recovery has been identified to be a result of the combined effect of load ratio and rich carbon loading. The observed inefficient CO2 separation indicates significant potential to enhance energy efficiency. These results represent a pivotal step forward in electrochemically mediated CO2 capture technology, with promising potential for rapid industrial scale-up in the near future. |
| format |
Article/Letter to editor |
| topic_facet |
Bipolar membrane electrodialysis Carbon capture Electrochemical pH swing Integration Post-combustion Regeneration Scale-up |
| author |
Shi, Meng Vallejo Castaño, Sara Shu, Qingdian Tedesco, Michele Kuntke, Philipp Hamelers, Hubertus V.M. Loldrup Fosbøl, Philip |
| author_facet |
Shi, Meng Vallejo Castaño, Sara Shu, Qingdian Tedesco, Michele Kuntke, Philipp Hamelers, Hubertus V.M. Loldrup Fosbøl, Philip |
| author_sort |
Shi, Meng |
| title |
Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation |
| title_short |
Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation |
| title_full |
Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation |
| title_fullStr |
Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation |
| title_full_unstemmed |
Carbon capture via electrochemically mediated alkaline absorption : Lab-scale continuous operation |
| title_sort |
carbon capture via electrochemically mediated alkaline absorption : lab-scale continuous operation |
| url |
https://research.wur.nl/en/publications/carbon-capture-via-electrochemically-mediated-alkaline-absorption |
| work_keys_str_mv |
AT shimeng carboncaptureviaelectrochemicallymediatedalkalineabsorptionlabscalecontinuousoperation AT vallejocastanosara carboncaptureviaelectrochemicallymediatedalkalineabsorptionlabscalecontinuousoperation AT shuqingdian carboncaptureviaelectrochemicallymediatedalkalineabsorptionlabscalecontinuousoperation AT tedescomichele carboncaptureviaelectrochemicallymediatedalkalineabsorptionlabscalecontinuousoperation AT kuntkephilipp carboncaptureviaelectrochemicallymediatedalkalineabsorptionlabscalecontinuousoperation AT hamelershubertusvm carboncaptureviaelectrochemicallymediatedalkalineabsorptionlabscalecontinuousoperation AT loldrupfosbølphilip carboncaptureviaelectrochemicallymediatedalkalineabsorptionlabscalecontinuousoperation |
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1819140296629288960 |