LAPSE:2025.0258
Published Article
LAPSE:2025.0258
Olefins production through sustainable pathways: techno-economic and environmental assessment
June 27, 2025
Abstract
This study presents a comparative analysis of various configurations for sustainable olefins production via chemical recycling of plastic/biomass wastes, integrating CO2 capture, storage and management technologies. The co-gasification, methanol synthesis and methanol-to-olefins process models were developed on the Aspen Plus® software. Optimization of processing conditions is achieved through the OSMOSE Lua platform, for minimizing the total cost of operation while accounting for seasonal variability in the electricity prices. CO2 valorization processes have been shown to increase carbon efficiency from 55% up to 97% compared to steam naphtha cracking, making chemical recycling of plastics an appealing alternative. In addition, direct CO2 emissions can be fully eliminated, resulting in up to 70% lower net CO2 emissions even when fossil-based plastic waste is used as feedstock. Seasonal CO2 storage can extend the economic benefits by acting as a buffer against high electricity costs and serving as a feedstock for CO2 valorization processes when excess renewable electricity is available. The benefits of the proposed configurations are expected to become increasingly significant with the decarbonization of the electricity generation, relying more on renewable resources.
This study presents a comparative analysis of various configurations for sustainable olefins production via chemical recycling of plastic/biomass wastes, integrating CO2 capture, storage and management technologies. The co-gasification, methanol synthesis and methanol-to-olefins process models were developed on the Aspen Plus® software. Optimization of processing conditions is achieved through the OSMOSE Lua platform, for minimizing the total cost of operation while accounting for seasonal variability in the electricity prices. CO2 valorization processes have been shown to increase carbon efficiency from 55% up to 97% compared to steam naphtha cracking, making chemical recycling of plastics an appealing alternative. In addition, direct CO2 emissions can be fully eliminated, resulting in up to 70% lower net CO2 emissions even when fossil-based plastic waste is used as feedstock. Seasonal CO2 storage can extend the economic benefits by acting as a buffer against high electricity costs and serving as a feedstock for CO2 valorization processes when excess renewable electricity is available. The benefits of the proposed configurations are expected to become increasingly significant with the decarbonization of the electricity generation, relying more on renewable resources.
Record ID
Keywords
Circular Economy, Gasification, Light Olefins, Plastic Waste, Process Integration, Renewable and Sustainable Energy
Subject
Suggested Citation
Boztas O, Domingos MEGR, Flórez-Orrego DA, Maréchal F. Olefins production through sustainable pathways: techno-economic and environmental assessment. Systems and Control Transactions 4:662-667 (2025) https://doi.org/10.69997/sct.138183
Author Affiliations
Boztas O: Industrial Process and Energy Systems Engineering, EPFL, Sion, Valais, Switzerland
Domingos MEGR: Industrial Process and Energy Systems Engineering, EPFL, Sion, Valais, Switzerland
Flórez-Orrego DA: Industrial Process and Energy Systems Engineering, EPFL, Sion, Valais, Switzerland
Maréchal F: Industrial Process and Energy Systems Engineering, EPFL, Sion, Valais, Switzerland
Domingos MEGR: Industrial Process and Energy Systems Engineering, EPFL, Sion, Valais, Switzerland
Flórez-Orrego DA: Industrial Process and Energy Systems Engineering, EPFL, Sion, Valais, Switzerland
Maréchal F: Industrial Process and Energy Systems Engineering, EPFL, Sion, Valais, Switzerland
Journal Name
Systems and Control Transactions
Volume
4
First Page
662
Last Page
667
Year
2025
Publication Date
2025-07-01
Version Comments
Original Submission
Other Meta
PII: 0662-0667-1682-SCT-4-2025, Publication Type: Journal Article
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LAPSE:2025.0258
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https://doi.org/10.69997/sct.138183
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Jun 27, 2025
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Links to Related Works
References Cited
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