Modelling microplastics in the river thames: Sources, sinks and policy implications

Paul G. Whitehead; Gianbattista Bussi; Jocelyne M.R. Hughes; Ana T. Castro-Castellon; Magnus D. Norling; Elizabeth S. Jeffers; Cordelia P.N. Rampley; Daniel S. Read; Alice A. Horton

doi:10.3390/w13060861

Modelling microplastics in the river thames: Sources, sinks and policy implications

Paul G. Whitehead^*, Gianbattista Bussi, Jocelyne M.R. Hughes, Ana T. Castro-Castellon, Magnus D. Norling, Elizabeth S. Jeffers, Cordelia P.N. Rampley, Daniel S. Read, Alice A. Horton

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

48 Citations (Scopus)

Abstract

With widespread, long-term historical use of plastics and the presence of microplastics in a range of new and existing products, there is rising concern about their potential impacts on freshwater ecosystems. Understanding how microplastics are transported and distributed along river systems is key to assessing impacts. Modelling the main flow dynamics, mixing, sedimentation and resuspension processes is essential for an understanding of the transport processes. We use the new, processed based, dynamic, integrated catchments (INCA) microplastics model and apply this to the whole of the freshwater catchment of the River Thames, UK, to evaluate inputs, loads and concentrations along the river system. Recent data from UK water industry studies on microplastics in effluent discharges and sewage sludge disposal has been utilised to drive the INCA microplastics model. Predicted concentrations and microplastic loads moving along the river system are shown to be significant, with a build-up of concentrations along the river, with increasing deposition on the riverbed. The potential impacts on aquatic ecosystems are evaluated and a review of policy implications is explored.

Original language	English
Article number	861
Journal	Water (Switzerland)
Volume	13
Issue number	6
DOIs	https://doi.org/10.3390/w13060861
Publication status	Published - 22 Mar 2021

Bibliographical note

Funding Information:
Acknowledgments: The authors are very grateful to the University of Oxford for funding this research and to UKWIR for permission to quote the MP data from their recent report Ref. 19/EQ/01/18 (see Ball et al., 2020 [18]). We also thank the UK Government Department DEFRA for excellent feedback, especially on the policy aspects. The views in this paper however represent those of the authors.

Funding Information:
Funding: This research was supported by Oxford University Internal Research Funds.

Publisher Copyright:
© 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Research Groups and Themes

Organic & Biological

Keywords

Aquatic ecology
Microplastics
Pollution
River Thames
Water quality

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.3390/w13060861Licence: CC BY

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Cite this

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title = "Modelling microplastics in the river thames: Sources, sinks and policy implications",

abstract = "With widespread, long-term historical use of plastics and the presence of microplastics in a range of new and existing products, there is rising concern about their potential impacts on freshwater ecosystems. Understanding how microplastics are transported and distributed along river systems is key to assessing impacts. Modelling the main flow dynamics, mixing, sedimentation and resuspension processes is essential for an understanding of the transport processes. We use the new, processed based, dynamic, integrated catchments (INCA) microplastics model and apply this to the whole of the freshwater catchment of the River Thames, UK, to evaluate inputs, loads and concentrations along the river system. Recent data from UK water industry studies on microplastics in effluent discharges and sewage sludge disposal has been utilised to drive the INCA microplastics model. Predicted concentrations and microplastic loads moving along the river system are shown to be significant, with a build-up of concentrations along the river, with increasing deposition on the riverbed. The potential impacts on aquatic ecosystems are evaluated and a review of policy implications is explored.",

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note = "Funding Information: Acknowledgments: The authors are very grateful to the University of Oxford for funding this research and to UKWIR for permission to quote the MP data from their recent report Ref. 19/EQ/01/18 (see Ball et al., 2020 [18]). We also thank the UK Government Department DEFRA for excellent feedback, especially on the policy aspects. The views in this paper however represent those of the authors. Funding Information: Funding: This research was supported by Oxford University Internal Research Funds. Publisher Copyright: {\textcopyright} 2021 by the authors. Licensee MDPI, Basel, Switzerland.",

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AU - Hughes, Jocelyne M.R.

AU - Castro-Castellon, Ana T.

AU - Norling, Magnus D.

AU - Jeffers, Elizabeth S.

AU - Rampley, Cordelia P.N.

AU - Read, Daniel S.

AU - Horton, Alice A.

N1 - Funding Information: Acknowledgments: The authors are very grateful to the University of Oxford for funding this research and to UKWIR for permission to quote the MP data from their recent report Ref. 19/EQ/01/18 (see Ball et al., 2020 [18]). We also thank the UK Government Department DEFRA for excellent feedback, especially on the policy aspects. The views in this paper however represent those of the authors. Funding Information: Funding: This research was supported by Oxford University Internal Research Funds. Publisher Copyright: © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

PY - 2021/3/22

Y1 - 2021/3/22

N2 - With widespread, long-term historical use of plastics and the presence of microplastics in a range of new and existing products, there is rising concern about their potential impacts on freshwater ecosystems. Understanding how microplastics are transported and distributed along river systems is key to assessing impacts. Modelling the main flow dynamics, mixing, sedimentation and resuspension processes is essential for an understanding of the transport processes. We use the new, processed based, dynamic, integrated catchments (INCA) microplastics model and apply this to the whole of the freshwater catchment of the River Thames, UK, to evaluate inputs, loads and concentrations along the river system. Recent data from UK water industry studies on microplastics in effluent discharges and sewage sludge disposal has been utilised to drive the INCA microplastics model. Predicted concentrations and microplastic loads moving along the river system are shown to be significant, with a build-up of concentrations along the river, with increasing deposition on the riverbed. The potential impacts on aquatic ecosystems are evaluated and a review of policy implications is explored.

AB - With widespread, long-term historical use of plastics and the presence of microplastics in a range of new and existing products, there is rising concern about their potential impacts on freshwater ecosystems. Understanding how microplastics are transported and distributed along river systems is key to assessing impacts. Modelling the main flow dynamics, mixing, sedimentation and resuspension processes is essential for an understanding of the transport processes. We use the new, processed based, dynamic, integrated catchments (INCA) microplastics model and apply this to the whole of the freshwater catchment of the River Thames, UK, to evaluate inputs, loads and concentrations along the river system. Recent data from UK water industry studies on microplastics in effluent discharges and sewage sludge disposal has been utilised to drive the INCA microplastics model. Predicted concentrations and microplastic loads moving along the river system are shown to be significant, with a build-up of concentrations along the river, with increasing deposition on the riverbed. The potential impacts on aquatic ecosystems are evaluated and a review of policy implications is explored.

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Modelling microplastics in the river thames: Sources, sinks and policy implications

Abstract

Bibliographical note

Research Groups and Themes

Keywords

UN SDGs

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