Effects of biofouling on the sinking behavior of microplastics

Kaiser, David; Kowalski, Nicole; Waniek, Joanna J

doi:10.1088/1748-9326/aa8e8b

Cited by 485 publications

(254 citation statements)

References 35 publications

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“…This resulted in negative correlations of both TEP (particles L −1 , Spearman rho=−0.69, p=0.001, n=18) and CSP (particles L −1 , Spearman rho=−0.49, p=0.04, n=18), as well as in the number of Synechococcus cells (Spearman rho = −0.860.65, p<0.0001, n=33) to microplastics concentration ( figure S2). This suggests that biological production and rapid aggregation of organic gels are a possible removal mechanism of microplastics from the water column, supporting recent observations (Kaiser et al 2017, Michels et al 2018. The presence of both heterotrophic bacteria and suspended particles may increase the stickiness of Synechococcus-derived TEP or its precursors, enhancing cell aggregation and export (Deng et al 2015, Cruz andNeuer 2019).…”

Section: Resultssupporting

confidence: 74%

Microplastics increase the marine production of particulate forms of organic matter

Galgani

Tsapakis

Pitta

et al. 2019

Environ. Res. Lett.

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Microplastics are a major environmental challenge, being ubiquitous and persistent as to represent a new component in all marine environments. As any biogenic particle, microplastics provide surfaces for microbial growth and biofilm production, which largely consists of carbohydrates and proteins. Biofilms influence microbial activity and modify particle buoyancy, and therefore control the fate of microplastics at sea. In a simulated 'plastic ocean', three mesocosms containing oligotrophic seawater were amended with polystyrene microbeads and compared to three control mesocosms. The evolution of organic matter, microbial communities and nutrient concentrations was monitored over 12 days. The results indicated that microplastics increased the production of organic carbon and its aggregation into gel particulates. The observed increase of gel-like organics has implications on the marine biological pump as well as the transport of microplastics in the ocean.

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Section: Resultssupporting

confidence: 74%

Microplastics increase the marine production of particulate forms of organic matter

Galgani

Tsapakis

Pitta

et al. 2019

Environ. Res. Lett.

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“…(5) Plastic buoyancy may be affected by biofouling (Kooi et al 2017). Epibionts growing on plastic particles add mass and, depending on the organism's specific density, cause changes in overall buoyancy of the fouled particle (Zettler et al 2013), increasing settling velocity (Kaiser et al 2017). These effects are more important on particles with large surface area to volume ratios that have lower initial buoyancy (Ryan 2015) and can rapidly lead to sinking of fouled particles (Fazey and Ryan 2016).…”

Section: How Plastic Particles Sink From the Ocean Surfacementioning

confidence: 99%

“…The dynamics of fibres or very small plastics, on the other hand, remains poorly documented, and overall the interaction between particles and turbulence is a major knowledge gap in a realistic description of the vertical distribution of plastics in the ocean. More experiments are also needed to parameterise the influence of plastic degradation and biofilm formation on the rise/settling velocity (Kaiser et al 2017). The vertical distribution is also influenced by particle concentration, through affecting the turbulence (Bennett et al 2013), and size (Bennett et al 2014).…”

Section: Laboratory Experimentsmentioning

confidence: 99%

The physical oceanography of the transport of floating marine debris

Sebille

Aliani

Law

et al. 2020

Environ. Res. Lett.

564

267

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Marine plastic debris floating on the ocean surface is a major environmental problem. However, its distribution in the ocean is poorly mapped, and most of the plastic waste estimated to have entered the ocean from land is unaccounted for. Better understanding of how plastic debris is transported from coastal and marine sources is crucial to quantify and close the global inventory of marine plastics, which in turn represents critical information for mitigation or policy strategies. At the same time, plastic is a unique tracer that provides an opportunity to learn more about the physics and dynamics of our ocean across multiple scales, from the Ekman convergence in basin-scale gyres to individual waves in the surfzone. In this review, we comprehensively discuss what is known about the different processes that govern the transport of floating marine plastic debris in both the open ocean and the coastal zones, based on the published literature and referring to insights from neighbouring fields such as oil spill dispersion, marine safety recovery, plankton connectivity, and others. We discuss how measurements of marine plastics (both in situ and in the laboratory), remote sensing, and numerical simulations can elucidate these processes and their interactions across spatio-temporal scales. Environ. Res. Lett. 15 (2020) 023003 E van Sebille et al Environ. Res. Lett. 15 (2020) 023003 E van Sebille et al References Acha E M, Mianzan H W, Iribarne O, Gagliardini D A, Lasta C and Daleo P 2003 The role of the Rı́o de la Plata bottom salinity front in accumulating debris Mar. Pollut. Bull. 46 197-202 Acha E M, Piola A, Iribarne O and Mianzan H 2015 Ecological Processes at Marine Fronts: Oases in the Ocean (Berlin: Springer) Aliani S and Molcard A 2003 Hitch-hiking on floating marine debris: macrobenthic species in the Western Mediterranean Sea Hydrobiologia 503 59-67 Allen J 1985 Principles of Physical Sedimentology (Berlin: Springer) Alpers W 1985 Theory of radar imaging of internal waves Nature 314 245-7 Alsina J M and Cáceres I 2011 Sediment suspension events in the inner surf and swash zone. Measurements in large-scale and high-energy wave conditions Coast. Eng. 58

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“…Numerical modelling is a promising tool to elaborate the required holistic view of MPs (as well as marine plastic litter in general) in the world ocean. In its turn, relevant modeling depends on thorough conception of MPs dynamics in the real environment; however, only initial steps have been made in this regard (Ballent et al 2012;Reisser et al 2015;Chubarenko et al 2016;Kaiser et al 2017;Khatmullina and Isachenko 2017;Kooi et al 2017). In contrast, behavior of other particles in the water column (e.g., natural sediment grains, fecal pellets, phytoplankton) have been quite extensively studied in sedimentology and hydrodynamics (e.g., Soulsby 1997;Turner 2002).…”

Section: Introductionmentioning

confidence: 99%

Transport of marine microplastic particles: why is it so difficult to predict?

Khatmullina

Chubarenko

2019

Anthropocene Coasts

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Marine microplastic particles (MPs, <5 mm) exhibit wide ranges of densities, sizes, and shapes, so that the entire MPs “ensemble” at every time instant can be characterized by continuous distributions of these parameters. Accordingly, this community of particles demonstrates distributions of dynamical properties, such as sinking or rising velocity, critical shear stress, and the re-suspension threshold. Moreover, all the MPs’ properties vary significantly with the time spent in marine environment and with particular conditions experienced by the particle on its journey. A brief review of the present-day numerical efforts towards prediction of MPs transport shows the prevalence of the Lagrangian particle tracking approach, especially for floating litter. In a broader context, the present practice of MPs transport modelling follows the “selective” strategy (e.g., only a certain sub-class of MPs, or specific processes, are considered, sometimes in only one- or two-dimensional setting). The heterogeneous nature of MPs, their enormous longevity and movability in marine environment, and the wide spectrum of the involved environmental processes suggest further integration (or coupling) of different models in future, as well as application of other types of models (ensemble modeling, chaos theory approaches, machine learning, etc.) to the problems of MPs transport and fate in the marine environment.

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Effects of biofouling on the sinking behavior of microplastics

Cited by 485 publications

References 35 publications

Microplastics increase the marine production of particulate forms of organic matter

Microplastics increase the marine production of particulate forms of organic matter

The physical oceanography of the transport of floating marine debris

Transport of marine microplastic particles: why is it so difficult to predict?

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