Resource availability for e-MGO adoption in maritime transport: A case study in the Port of Barcelona

[Display omitted] •Electro-fuels as a promising option for decarbonizing maritime transport.•Co-electrolysis and Fischer–Tropsch a two-step efficient energy process.•Expanding renewable energy capacity essential for e-fuel development.•Biomethane sector will be key to biogenic carbon dioxide supply....

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Bibliographic Details
Published in:Energy conversion and management. X 2024-10, Vol.24, p.100800, Article 100800
Main Authors: Quintana, Karen, García Blanco, Andrés A., Bernadet, Lucile, Ruiz, Daniel, Torrell, Marc, Guilera, Jordi
Format: Article
Language:English
Subjects:
Biogenic CO2
Co-electrolysis
Electro-fuels
Fischer-Tropsch Synthesis
Marine gas oil
Renewable resources
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Summary:[Display omitted] •Electro-fuels as a promising option for decarbonizing maritime transport.•Co-electrolysis and Fischer–Tropsch a two-step efficient energy process.•Expanding renewable energy capacity essential for e-fuel development.•Biomethane sector will be key to biogenic carbon dioxide supply.•Water availability unlikely to limit marine electro-fuels production. Power-to-Liquid processes have the potential to decarbonize maritime transport by producing carbon–neutral electro-fuels. One example of a potential implementation of this process is the combined technology of co-electrolysis of carbon dioxide and water, along with Fischer–Tropsch Synthesis. Given the promising prospects of producing electro-fuels to achieve net-zero objectives by 2050, a critical question that arises is whether sufficient resources are available to replace the current demand for fossil marine gas oil (MGO). This study evaluates the requirements and availability of resources necessary for producing marine electro-fuel using the MGO demand at the Port of Barcelona as a case study. The results indicate that current supplies of renewable energy and biogenic CO2 are insufficient to fully replace the total fossil MGO demand. However, by 2050, it is expected that these resource limitations will be overcome, considering the current official projections for the growth of renewable electricity and the biogas industry. The deployment of renewable electricity generation and the rollout of biomethane industrial network as biogenic carbon source is found to be essential for the viability of the future substitution of fossil MGO with its electro-fuel equivalent.
ISSN:2590-1745
2590-1745
DOI:10.1016/j.ecmx.2024.100800