Modeling drift and fate of microplastics in the Baltic Sea

Murawski, Jens; She, Jun; Frishfelds, Vilnis

doi:10.3389/fmars.2022.886295

Cited by 15 publications

(3 citation statements)

References 44 publications

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“…Hydrodynamic conditions for both the near-field and far-field models were simulated with the HBM three-dimensional baroclinic ocean circulation model employed for the Baltic Sea forecasting service (SI section S3). − …”

Section: Methodsmentioning

confidence: 99%

Fate of Methane from the Nord Stream Pipeline Leaks

Dissanayake,

Gros,

Drews

et al. 2023

Environ. Sci. Technol. Lett.

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In September 2022, three major subsea leaks occurred in the Nord Stream pipelines, releasing an estimated 225 kt of natural gas into the Baltic Sea. To explain its behavior in the water column, we developed a combined model to simulate the near-field buoyant bubble plumes and the far-field advection, dispersion, volatilization, and biodegradation of the dissolved methane fraction. According to these simulations, 94.9% of the leaked methane was emitted to the atmosphere immediately above the leaks by ascending gas bubble plumes. The remaining 5.1% of the methane (11 kt) initially dissolved, leading to concentrations of up to 625,000 nM or 5 orders of magnitude above the local Baltic Sea natural background. The modeling suggests that within 35 days, 71.4% of the dissolved methane volatilized and 26.0% biodegraded, and the maximum water column concentration decreased to 70 nM. We find that up to 409 km3 of seawater experienced concentrations greater than 10 times above the natural background. The modeling shows that more than 10 marine protected areas in the Baltic Sea were exposed to elevated dissolved methane concentrations.

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Section: Methodsmentioning

confidence: 99%

Fate of Methane from the Nord Stream Pipeline Leaks

Dissanayake,

Gros,

Drews

et al. 2023

Environ. Sci. Technol. Lett.

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“…Biofilm growth was calculated as a function of ecological and environmental parameters, derived from biogeochemical models. For the Baltic Sea, chlorophyll a concentration was used to calculate biofilm growth (Murawski et al, 2022), while for the Mediterranean Sea, algae concentration was used (Tsiaras et al, 2021).…”

Section: Marine Plastic Modeling and Assessmentmentioning

confidence: 99%

Developing Realistic Models for Assessing Marine Plastic Pollution in Semi-Enclosed Seas

She¹,

Christensen²,

Garaventa³

et al. 2023

Oceanog

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Having steadily increased with global production in the past 50 years, the presence and accumulation of plastic debris is now recognized as a major environmental problem, with consequences directly affecting not only marine ecosystems, but also society and human well-being. After human activities release plastic litter, it is either directly discharged into the ocean or it is transported to the sea via inland pathways (e.g., rivers, lakes, wastewater treatment plants). Once in the ocean, plastics are further transported and transformed by processes such as ocean currents, winds and waves, water dispersion, fragmentation, biofouling, sinking, sedimentation, and beaching (Figure 1).

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“…Plastic products are widely used in human life and industry production due to their low cost, high ductility and stable properties (Paul-Pont et al, 2018;Murawski et al, 2022). Plastics can be classified into five types according to diameter: macroplastics (>25 mm), mesoplastics (1-25 mm), large microplastics (1-5 mm), small microplastics (1-1000 mm), and nanoplastics(<1 mm) (Eriksen et al, 2014;Dris et al, 2015;Alimi et al, 2018;Hanvey, 2023).…”

Section: Introductionmentioning

confidence: 99%

Clogging risk of microplastics particles in porous media during artificial recharge: a laboratory experiment

Wang,

Zhang,

Chen

et al. 2024

Front. Mar. Sci.

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Management aquifer recharge (MAR) technology is widely applied to solve seawater intrusion caused by groundwater overexploitation in coastal areas. However, MAR creates an important pathway for microplastics (particle size< 5 mm) to enter groundwater. To explore the clogging potential of microplastics in aquifer media, a series of laboratory-scale column experiments were conducted in this study. The hydraulic conductivity of porous media and deposition amount of microplastics were investigated under different experimental conditions. In our study, most of the microplastics were intercepted in the sand column’s surface layer. The difference of particle size in porous media greatly influence the clogging development. The hydraulic conductivity of the aquifer media decreased as the microplastic particle size decreased. When the particle size of microplastic was larger than 300 mm, most of the microplastics deposits on the surface of the porous media, forming a “microplastic accumulation layer”. Microplastics are affected by particle size, flow shear stress and preferential flow during migration. The migration ability of microplastics increased significantly with the increase of hydraulic head difference and decreased with the increase of sand column depth. The bacteria microorganisms are projected to be a new biological control strategy in conjunction with MAR. The study of clogging risk of microplastics particles in porous media during artificial recharge provides novel and unique insights for the management and control of microplastic pollution in groundwater systems.

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Modeling drift and fate of microplastics in the Baltic Sea

Cited by 15 publications

References 44 publications

Fate of Methane from the Nord Stream Pipeline Leaks

Fate of Methane from the Nord Stream Pipeline Leaks

Developing Realistic Models for Assessing Marine Plastic Pollution in Semi-Enclosed Seas

Clogging risk of microplastics particles in porous media during artificial recharge: a laboratory experiment

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