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Plastics in the global environment assessed through material flow analysis, degradation and environmental transportation

The Science of The Total Environment 2023 100 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 55 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

J.H. Urbanus, J.H. Urbanus, Luke A. Parker, Anna Schwarz Anna Schwarz Anna Schwarz Anna Schwarz Luke A. Parker, J.H. Urbanus, S.M.C. Lensen, J.H. Urbanus, S.M.C. Lensen, S.M.C. Lensen, Anna Schwarz S.M.C. Lensen, Anna Schwarz J.H. Urbanus, J.H. Urbanus, Luke A. Parker, Luke A. Parker, Luke A. Parker, Luke A. Parker, E. Langeveld, Luke A. Parker, Luke A. Parker, Luke A. Parker, Luke A. Parker, E. Langeveld, J.H. Urbanus, Luke A. Parker, J.H. Urbanus, Luke A. Parker, J.H. Urbanus, J.H. Urbanus, J.H. Urbanus, J.H. Urbanus, Luke A. Parker, Luke A. Parker, Luke A. Parker, Luke A. Parker, Anna Schwarz Anna Schwarz

Summary

Researchers conducted a global mass flow analysis of plastic emissions across all countries, tracking 8 polymer types across 10 sectors into 7 environmental compartments. The study estimated that 0.8 million tonnes of microplastics and 8.7 million tonnes of macroplastics entered the environment in 2017, with tire wear being the largest source of microplastic emissions. Modeling predicts that even with zero plastic production after 2022, approximately 2.15 gigatonnes of plastics would still accumulate in the environment by 2050 due to landfill leakage and degradation.

Polymers

rubber

Study Type Environmental

Knowledge on environmental plastic emission and spatial and temporal accumulation is vital for the development of successful mitigation strategies and risk assessments of plastics. In this study, emissions of both micro and macro plastic from the plastic value chain to the environment were assessed on a global level through a mass flow analysis (MFA). All countries, 10 sectors, 8 polymers and 7 environmental compartments (terrestrial, freshwater or oceanic) are distinguished in the model. The results assess a loss of 0.8 million tonnes (mt) of microplastics and 8.7 mt of macroplastics to the global environment in 2017. This is respectively 0.2 % and 2.1 % of plastics produced in the same year. The packaging sector contributed most for macroplastic emissions, and tyre wear for microplastic emissions. With the MFA results, accumulation, degradation and environmental transportation are considered in the Accumulation and dispersion model (ADM) until 2050. This model predicts macro- and microplastic accumulation in the environment to 2.2 gigatonnes (Gt) and 3.1 Gt in 2050 respectively (scenario: yearly consumption increase of 4 %). This will be 30 % less when a yearly production reduction of 1 % until 2050 is modeled to 1.5 and 2.3 Gt macro and microplastics respectively. Almost 2.15 Gt of micro and macroplastics accumulate in the environment until 2050 with zero plastic production after 2022 due to leakage from landfills and degradation processes. Results are compared to other modeling studies quantifying plastic emissions to the environment. The current study predicts lower emissions to ocean and higher emissions to surface waters like lakes and rivers. Non aquatic, terrestrial compartments are observed to accumulate most plastics emitted to the environment. The approach used results in a flexible and adaptable model that addresses plastic emissions to the environment over time and space, with detail on country level and environmental compartments.

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