Life cycle assessment (LCA) on waste management options for derelict fishing gear

Purpose Derelict fishing gear (DFG) is one of the most abundant and harmful types of marine litter that gets increasingly retrieved from the ocean. However, for this novel waste stream recycling and recovery pathways are not yet commonly established. To identify the most suitable waste management sy...

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Bibliographic Details
Published in:The international journal of life cycle assessment 2023-03, Vol.28 (3), p.274-290
Main Authors: Schneider, Falk, Parsons, Sophie, Clift, Sally, Stolte, Andrea, Krüger, Michael, McManus, Marcelle
Format: Article
Language:English
Subjects:
Earth and Environmental Science
Emissions
Energy recovery
Environment
Environmental Chemistry
Environmental Economics
Environmental Engineering/Biotechnology
Environmental impact
Fishing
Fishing equipment
Fishing gear
Landfill
Landfills
Lca of Waste Management Systems
Life cycle analysis
Life cycle assessment
Life cycles
Litter
Marine debris
Marine pollution
Recycling
Retrieval
Sensitivity analysis
Social factors
Synthesis gas
Toxicity
Transport processes
Uncertainty analysis
Waste disposal sites
Waste management
Waste streams
Waste treatment
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Summary:Purpose Derelict fishing gear (DFG) is one of the most abundant and harmful types of marine litter that gets increasingly retrieved from the ocean. However, for this novel waste stream recycling and recovery pathways are not yet commonly established. To identify the most suitable waste management system, this study assesses the potential environmental impacts of DFG waste treatment options in Europe. Methods This study applies an attributional life cycle assessment (LCA) to four DFG waste treatment scenarios, namely a mechanical recycling, syngas production, energy recovery and landfill disposal. The scope spans from the retrieval and transport processes to pre- and end-treatment steps until the outputs are sent to landfill or assumed to substitute products or energy. Primary data was collected from retrieval and waste treatment trials in Europe. Contribution, sensitivity and uncertainty analyses were conducted using the LCA software SimaPro and ReCiPe as the impact methodology. Results and discussion The results show that the mechanical recycling and energy recovery achieve the lowest potential environmental impacts. The syngas production and landfill disposal scenario are not environmentally competitive because they require too much electricity, or their avoided production credits were too small to offset their emissions. Unlike the pre-treatment and transport processes, the retrieval and end-treatment processes have a significant impact on the overall results. The transport distances, energy mix and market and technological assumptions are least sensitive, while changes to the waste composition significantly affect the results. Especially a reduced lead content benefits the human toxicity impact potential of the landfill disposal scenario. The uncertainty analysis showed that the results are very robust in nine of twelve impact categories. Conclusions This is the first LCA study that compares waste treatment options for marine litter. The results indicate that a disposal of DFG is hazardous and should be replaced with mechanical recycling or energy recovery. While this may be technologically possible and environmentally beneficial, economic and social factors should also be considered before a final decision is made. To further reduce environmental impacts, marine litter prevention should play a more important role. Graphical abstract
ISSN:0948-3349
1614-7502
DOI:10.1007/s11367-022-02132-y