The role of abiotic and biotic aging in the elimination of polyethylene microplastics by coagulation

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Authors
Ziembowicz, Sabina ORCID logo 0000-0002-8032-5168
Kida, Małgorzata ORCID logo 0000-0003-1744-4014
Koszelnik, Piotr ORCID logo 0000-0001-6866-7432
Zdeb, Monika ORCID logo 0000-0002-3565-080X
Baluk, Mateusz ORCID logo 0000-0003-1174-5182
Date
2026-03
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Creative Commons License
Attribution 4.0 International
Abstract
Coagulation has been extensively examined for the removal of microplastics from water; however, to date, there is a significant lack of knowledge regarding the removal efficiency of aged microplastics. To address this challenge, this study investigates the effects of abiotic and biotic aging on microplastic properties and coagulation efficiency. Mechanical, thermal, biological, and combined mechanical-biological aging of polyethylene (PE) were conducted. The influence of time (7, 14, 28, and 60 days), pH (3, 7, and 10), temperature (5, 25, and 60 °C), and the presence of sand particles and sunlight was analyzed. All aging factors affected removal efficiency, which ranged from 27.93% to 56.79% for mechanical aging, 26.98% to 57.80% for thermal aging, 59.52% to 66.97% for biotic aging, and 44.92% to 65.48% for combined mechanical–biotic aging. The most significant effect was observed following biotic incubation of PE with Pseudomonas aeruginosa, due to biofilm formation on the PE surface. After 7, 14, and 28 days of incubation, the measured biofilm amounts were 70.2, 121.6, and 149.6 mg/g, respectively. Biofilm formation led to an increase in sinking ratio from 0.01 for pristine PE to 0.068, 0.07, and 0.1425 after 7, 14, and 28 days, respectively. FT-IR analysis revealed signals at approximately 2100 cm⁻¹ (C≡N group) and 1100 cm⁻¹ (nucleic acid residues), along with increased carbonyl index values, indicating biofilm formation during incubation with P. aeruginosa. LDIR analysis showed a reduction in PE particle size following thermal and mechanical aging, whereas an increase in particle size was observed after biological aging.
Description
Wyniki opublikowane w tym artykule to dane uzyskane w ramach projektu OPUS 27 pt.” Rola starzenia abiotycznego i biotycznego w usuwaniu mikroplastików w procesie koagulacji z wykorzystaniem naturalnych i odpadowych koagulantów” (2024/53/B/ST8/03010, NCN).
Description
Wyniki opublikowane w tym artykule to dane uzyskane w ramach projektu OPUS 27 pt.” Rola starzenia abiotycznego i biotycznego w usuwaniu mikroplastików w procesie koagulacji z wykorzystaniem naturalnych i odpadowych koagulantów” (2024/53/B/ST8/03010, NCN).
Keywords
microplastics aging  biofilm formation  mechanical and thermal treatment  sinking ratio  LDIR analysis
Citation
Ziembowicz S., Kida M., Koszelnik P., Zdeb M., Baluk M. The role of abiotic and biotic aging in the elimination of polyethylene microplastics by coagulation. Science of the Total Environment 1023 (2026) 181633. https://doi.org/10.1016/j.scitotenv.2026.181633
URI
https://open.icm.edu.pl/handle/123456789/26609
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