Role of saltmarsh systems in estuarine trapping of microplastics
Role of saltmarsh systems in estuarine trapping of microplastics
Saltmarshes are important natural ecosystems along many temperate (and other) coastlines. They stabilize sediments and act as biofilters for a range of industrial pollutants and, potentially, microplastics. Accumulation of microplastics along estuarine coastlines may be enhanced by the presence of saltmarsh species, as they offer better particle trapping efficiency than adjacent intertidal mudflats under prevailing flood and ebb tidal currents. However, the trapping efficiency of entire saltmarsh systems under varying flow conditions has not been widely assessed. While the effects of saltmarsh systems on water flow, and on sediment transport and trapping, have been relatively well studied, little is known about the contributions of saltmarsh halophytes, resident organisms and the associated saltmarsh sediments to the trapping of microplastics. To address this, a series of flume experiments were undertaken to examine transport and accumulation of Bakelite particles (~ 500 µm) and PVC nurdles (~ 5 mm) as model plastics in sub-sampled saltmarsh and intertidal mudflat monoliths. The results showed that saltmarsh systems influenced the hydrodynamics within and above the canopy, enhancing turbulence and shear stresses. With increasing flow velocities (≤ 0.51 m s−1), negligible quantities (2 × 10−4 mg L−1) of sediments and Bakelite particles were eroded and resuspended. The algal biogenic roughness from the mudflat, and the vegetative roughness from the Spartina plants on the saltmarsh, inhibited the transportation of the microplastics within the tested systems. Resident burrowing crabs (Carcinus maenas) promoted the burial, release and transport of microplastics. The results of this study provide evidence of the contributory roles of saltmarsh systems in the sequestration of microplastics and sediment stabilization. Estuarine saltmarsh systems can act as sinks for microplastics with enhanced burial from burrowing crabs under favourable flow conditions.
ESTUARIES, Intertidal ecosystems, Microplastics, Nature-based solutions, Saltmarshes
Ogbuagu, Chiedozie Collins
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Kassem, Hachem
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Udiba, Udiba U.
1f7d6da3-8107-4eac-a0d1-a03c0c6f2e92
Stead, Jessica Laura
abd3bc01-cf97-4692-a191-cd3ce2fb79f7
Cundy, Andy
994fdc96-2dce-40f4-b74b-dc638286eb08
15 September 2022
Ogbuagu, Chiedozie Collins
8bc76164-dc85-4df4-a426-4fa110083958
Kassem, Hachem
658efa7a-a02c-4b29-9d07-5d57e95a4b51
Udiba, Udiba U.
1f7d6da3-8107-4eac-a0d1-a03c0c6f2e92
Stead, Jessica Laura
abd3bc01-cf97-4692-a191-cd3ce2fb79f7
Cundy, Andy
994fdc96-2dce-40f4-b74b-dc638286eb08
Ogbuagu, Chiedozie Collins, Kassem, Hachem, Udiba, Udiba U., Stead, Jessica Laura and Cundy, Andy
(2022)
Role of saltmarsh systems in estuarine trapping of microplastics.
Scientific Reports, 12 (1), [15546].
(doi:10.1038/s41598-022-18881-7).
Abstract
Saltmarshes are important natural ecosystems along many temperate (and other) coastlines. They stabilize sediments and act as biofilters for a range of industrial pollutants and, potentially, microplastics. Accumulation of microplastics along estuarine coastlines may be enhanced by the presence of saltmarsh species, as they offer better particle trapping efficiency than adjacent intertidal mudflats under prevailing flood and ebb tidal currents. However, the trapping efficiency of entire saltmarsh systems under varying flow conditions has not been widely assessed. While the effects of saltmarsh systems on water flow, and on sediment transport and trapping, have been relatively well studied, little is known about the contributions of saltmarsh halophytes, resident organisms and the associated saltmarsh sediments to the trapping of microplastics. To address this, a series of flume experiments were undertaken to examine transport and accumulation of Bakelite particles (~ 500 µm) and PVC nurdles (~ 5 mm) as model plastics in sub-sampled saltmarsh and intertidal mudflat monoliths. The results showed that saltmarsh systems influenced the hydrodynamics within and above the canopy, enhancing turbulence and shear stresses. With increasing flow velocities (≤ 0.51 m s−1), negligible quantities (2 × 10−4 mg L−1) of sediments and Bakelite particles were eroded and resuspended. The algal biogenic roughness from the mudflat, and the vegetative roughness from the Spartina plants on the saltmarsh, inhibited the transportation of the microplastics within the tested systems. Resident burrowing crabs (Carcinus maenas) promoted the burial, release and transport of microplastics. The results of this study provide evidence of the contributory roles of saltmarsh systems in the sequestration of microplastics and sediment stabilization. Estuarine saltmarsh systems can act as sinks for microplastics with enhanced burial from burrowing crabs under favourable flow conditions.
Text
s41598-022-18881-7
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Accepted/In Press date: 22 August 2022
Published date: 15 September 2022
Additional Information:
© 2022. The Author(s).
Keywords:
ESTUARIES, Intertidal ecosystems, Microplastics, Nature-based solutions, Saltmarshes
Identifiers
Local EPrints ID: 470487
URI: http://eprints.soton.ac.uk/id/eprint/470487
ISSN: 2045-2322
PURE UUID: ea2de633-1b74-4124-aea8-3e6d39232707
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Date deposited: 11 Oct 2022 16:51
Last modified: 17 Mar 2024 03:38
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Contributors
Author:
Chiedozie Collins Ogbuagu
Author:
Udiba U. Udiba
Author:
Jessica Laura Stead
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