LAPSE:2025.0239
Published Article
LAPSE:2025.0239
Integration of renewable energy and reversible solid oxide cells to decarbonize secondary aluminium production and urban systems
June 27, 2025
Abstract
This study explores an energy transition strategy that leverages reversible solid oxide cells (rSOC), power-to-gas (PtG) conversion, and CO2 management to enhance the efficiency and sustainability of secondary aluminum production. A comparative analysis between conventional and integrated energy scenarios highlights the benefits of multi-technology integration. The results indicate that the integrated system increases total energy demand by 27% due to additional energy conversion steps, but eliminates natural gas consumption, reducing dependency on fossil fuels. Additionally, net CO2 emissions are reduced more than fivefold, demonstrating the potential of carbon capture and utilization strategies. The seasonal storage of synthetic natural gas (SNG) and biogenic CO2 further enhances system flexibility, allowing excess renewable electricity to be converted into storable fuels for winter use. Despite higher capital expenditures, the operational costs of the integrated system are 11% lower than the conventional approach due to improved energy efficiency and CO2 taxation savings. These findings underscore the importance of process integration, energy storage, and renewable electricity utilization in achieving a low-carbon, resilient aluminum industry and urban heating networks.
This study explores an energy transition strategy that leverages reversible solid oxide cells (rSOC), power-to-gas (PtG) conversion, and CO2 management to enhance the efficiency and sustainability of secondary aluminum production. A comparative analysis between conventional and integrated energy scenarios highlights the benefits of multi-technology integration. The results indicate that the integrated system increases total energy demand by 27% due to additional energy conversion steps, but eliminates natural gas consumption, reducing dependency on fossil fuels. Additionally, net CO2 emissions are reduced more than fivefold, demonstrating the potential of carbon capture and utilization strategies. The seasonal storage of synthetic natural gas (SNG) and biogenic CO2 further enhances system flexibility, allowing excess renewable electricity to be converted into storable fuels for winter use. Despite higher capital expenditures, the operational costs of the integrated system are 11% lower than the conventional approach due to improved energy efficiency and CO2 taxation savings. These findings underscore the importance of process integration, energy storage, and renewable electricity utilization in achieving a low-carbon, resilient aluminum industry and urban heating networks.
Record ID
Keywords
CO2 utilization, power-to-gas, process optimization, renewable energy integration, reversible solid oxide cells, Secondary aluminum
Subject
Suggested Citation
Flórez-Orrego D, Dardor D, Domingos MER, Germanier R, Maréchal F. Integration of renewable energy and reversible solid oxide cells to decarbonize secondary aluminium production and urban systems. Systems and Control Transactions 4:546-552 (2025) https://doi.org/10.69997/sct.188682
Author Affiliations
Flórez-Orrego D: Industrial Process and Energy Systems Engineering, EPFL, Sion, 1950, Switzerland
Dardor D: Industrial Process and Energy Systems Engineering, EPFL, Sion, 1950, Switzerland; Institute of Sustainable Energy, University of Applied Sciences and Arts Western (HES-SO), Sion, Switzerland
Domingos MER: Industrial Process and Energy Systems Engineering, EPFL, Sion, 1950, Switzerland
Germanier R: Novelis Switzerland S.A
Maréchal F: Industrial Process and Energy Systems Engineering, EPFL, Sion, 1950, Switzerland
Dardor D: Industrial Process and Energy Systems Engineering, EPFL, Sion, 1950, Switzerland; Institute of Sustainable Energy, University of Applied Sciences and Arts Western (HES-SO), Sion, Switzerland
Domingos MER: Industrial Process and Energy Systems Engineering, EPFL, Sion, 1950, Switzerland
Germanier R: Novelis Switzerland S.A
Maréchal F: Industrial Process and Energy Systems Engineering, EPFL, Sion, 1950, Switzerland
Journal Name
Systems and Control Transactions
Volume
4
First Page
546
Last Page
552
Year
2025
Publication Date
2025-07-01
Version Comments
Original Submission
Other Meta
PII: 0546-0552-1476-SCT-4-2025, Publication Type: Journal Article
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LAPSE:2025.0239
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https://doi.org/10.69997/sct.188682
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Jun 27, 2025
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References Cited
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