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Transport and burial of microplastics in deep-marine sediments by turbidity currents

Transport and burial of microplastics in deep-marine sediments by turbidity currents
Transport and burial of microplastics in deep-marine sediments by turbidity currents
The threat posed by plastic pollution to marine ecosystems and human health is under increasing scrutiny. Much of the macro- and microplastic in the ocean ends up on the seafloor, with some of the highest concentrations reported in submarine canyons that intersect the continental shelf and directly connect to terrestrial plastic sources. Gravity-driven avalanches, known as turbidity currents, are the primary process for delivering terrestrial sediment and organic carbon to the deep sea through submarine canyons. However, the ability of turbidity currents to transport and bury plastics is essentially unstudied. Using flume experiments, we investigate how turbidity currents transport microplastics, and their role in differential burial of microplastic fragments and fibers. We show that microplastic fragments become relatively concentrated within the base of turbidity currents, whereas fibers are more homogeneously distributed throughout the flow. Surprisingly, the resultant deposits show an opposing trend, as they are enriched with fibers, rather than fragments. We explain this apparent contradiction by a depositional mechanism whereby fibers are preferentially removed from suspension and buried in the deposits as they are trapped between settling sand-grains. Our results suggest that turbidity currents potentially distribute and bury large quantities of microplastics in seafloor sediments.
0013-936X
4180-4189
Pohl, Florian
7aebe37d-d7a0-4a95-8090-1806aa7e13b6
Eggenhuisen, Joris T.
157ad755-8819-48cb-8694-6bbffa20b727
Kane, Ian A.
dfdc39db-59b8-4b08-85e4-9d6d3a9cd41e
Clare, Michael A.
b26da858-9c08-4784-aaa9-7092efcd94bd
Pohl, Florian
7aebe37d-d7a0-4a95-8090-1806aa7e13b6
Eggenhuisen, Joris T.
157ad755-8819-48cb-8694-6bbffa20b727
Kane, Ian A.
dfdc39db-59b8-4b08-85e4-9d6d3a9cd41e
Clare, Michael A.
b26da858-9c08-4784-aaa9-7092efcd94bd

Pohl, Florian, Eggenhuisen, Joris T., Kane, Ian A. and Clare, Michael A. (2020) Transport and burial of microplastics in deep-marine sediments by turbidity currents. Environmental Science & Technology, 54 (7), 4180-4189. (doi:10.1021/acs.est.9b07527).

Record type: Article

Abstract

The threat posed by plastic pollution to marine ecosystems and human health is under increasing scrutiny. Much of the macro- and microplastic in the ocean ends up on the seafloor, with some of the highest concentrations reported in submarine canyons that intersect the continental shelf and directly connect to terrestrial plastic sources. Gravity-driven avalanches, known as turbidity currents, are the primary process for delivering terrestrial sediment and organic carbon to the deep sea through submarine canyons. However, the ability of turbidity currents to transport and bury plastics is essentially unstudied. Using flume experiments, we investigate how turbidity currents transport microplastics, and their role in differential burial of microplastic fragments and fibers. We show that microplastic fragments become relatively concentrated within the base of turbidity currents, whereas fibers are more homogeneously distributed throughout the flow. Surprisingly, the resultant deposits show an opposing trend, as they are enriched with fibers, rather than fragments. We explain this apparent contradiction by a depositional mechanism whereby fibers are preferentially removed from suspension and buried in the deposits as they are trapped between settling sand-grains. Our results suggest that turbidity currents potentially distribute and bury large quantities of microplastics in seafloor sediments.

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acs.est.9b07527 (1) - Version of Record
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Published date: 7 April 2020
Additional Information: Funding Information: We thank Thomas Bishop and John Moore in the Department of Geography at The University of Manchester for their help with the microplastics separation. M.C. was supported by the CLASS programme (NERC Grant No. NE/R015953/1). The comments of three anonymous reviewers helped to improve the scope and clarity of the paper. Publisher Copyright: © 2020 American Chemical Society.
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Local EPrints ID: 439732
URI: http://eprints.soton.ac.uk/id/eprint/439732
DOI: doi:10.1021/acs.est.9b07527
ISSN: 0013-936X
PURE UUID: 0f4a731f-79c4-48c9-bbe0-2c393494e0e8

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Date deposited: 30 Apr 2020 16:35
Last modified: 05 Jun 2024 17:33

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Contributors

Author: Florian Pohl
Author: Joris T. Eggenhuisen
Author: Ian A. Kane
Author: Michael A. Clare

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