IVL Swedish Environmental Research Institute

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  • 1. de los Santos, Carmen B.
    et al.
    Krång, Anna-Sara
    Infantes, Eduardo
    Microplastic retention by marine vegetated canopies: Simulations with seagrass meadows in a hydraulic flume2021In: Environmental Pollution, ISSN 0269-7491, E-ISSN 1873-6424, Vol. 269, p. 116050-116050, article id 116050Article in journal (Refereed)
    Abstract [en]

    Marine canopies formed by seagrass and other coastal vegetated ecosystems could act as sinks of microplastics for being efficient particle traps. Here we investigated for the first time the occurrence of microplastic retention by marine canopies in a hydraulic flume under unidirectional flow velocities from 2 to 30 cm s−1.

    We used as model canopy-forming species the seagrass Zostera marina with four canopy shoot density (0, 50, 100, 200 shoots m−2), and we used as microplastic particles industrial pristine pellets with specific densities from 0.90 to 1.34 g cm−3 (polypropylene PP; polystyrene PS; polyamide 6 PA; and polyethylene terephthalate PET). Overall, microplastics particles transported with the flow were retained in the seagrass canopies but not in bare sand. While seagrass canopies retained floating microplastics (PP) only at low velocities (<12 cm s−1) due to a barrier created by the canopy touching the water surface, the retention of sinking particles (PS, PA, PET) occurred across a wider range of flow velocities.

    Our simulations revealed that less dense sinking particles (PS) might escape from the canopy at high velocities, while denser sinking particles can be trapped in scouring areas created by erosive processes around the eelgrass shoots. Our results show that marine canopies might act as potential barriers or sinks for microplastics at certain bio-physical conditions, with the probability of retention generally increasing with the seagrass shoot density and polymer specific density and decreasing with the flow velocity.

    We conclude that seagrass meadows, and other aquatic canopy-forming ecosystems, should be prioritized habitats in assessment of microplastic exposure and impact on coastal areas since they may accumulate high concentration of microplastic particles that could affect associated fauna.

  • 2. Du, Yaxing
    et al.
    Isaxon, Christina
    Roldin, Pontus
    Mattisson, Kristoffer
    Karttunen, Sasu
    Li, Xiaoyu
    Malmqvist, Ebba
    Järvi, Leena
    Large-eddy simulation of aerosol concentrations in a realistic urban environment: Model validation and transport mechanism2024In: Environmental Pollution, ISSN 0269-7491, E-ISSN 1873-6424, Vol. 358, p. 124475-124475, article id 124475Article in journal (Refereed)
    Abstract [en]

    Air pollution in urban environments exhibits large spatial and temporal variations due to high heterogeneous air flow and emissions. To address the complexity of local air pollutant dynamics, a comprehensive large-eddy simulation using the PALM model system v6.0 was conducted. The distribution of flow and vehicle emitted aerosol particles in a realistic urban environment in Malmö, Sweden, was studied and evaluated against on-site measurements made using portable instrumentation on a spring morning in 2021.

    The canyon transport mechanisms were investigated, and the convective and turbulent mass-transport rates compared to clarify their role in aerosol transport. The horizontal distribution of aerosols showed acceptable evaluation metrics for both mass and number. Flow and pollutant concentrations were more complex than those in idealized street canyon networks. Vertical turbulent mass-transport rate was found to dominate the mass transport process compared with the convective transport rate, contributing more than 70% of the pollutant transport process.

    Our findings highlight the necessity of examining various aerosol metric due their distinct dispersion behaviour. This study introduces a comprehensive high-resolution modelling framework that accounts for dynamic meteorological and aerosol background boundary conditions, real-time traffic emission, and detailed building features, offering a robust toll for local urban air quality assessment.

  • 3.
    Eklöf, Karin
    et al.
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    von Brömssen, Claudia
    Department of Energy and Technology, Applied Statistics and Mathematics, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Huser, Brian
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Åkerblom, Staffan
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Augustaitis, Algirdas
    Faculty of Forest Sciences and Ecology, Agriculture Academy, Vytautas Magnus University, LT-53362, Kaunas dstr., Lithuania.
    Veiteberg Braaten, Hans Fredrik
    Norwegian Institute for Water Research (NIVA), Økernveien 94, 0579, Oslo, Norway.
    de Wit, Heleen A.
    Norwegian Institute for Water Research (NIVA), Økernveien 94, 0579, Oslo, Norway.
    Dirnböck, Thomas
    Ecosystem Research and Environmental Information Management, Environment Agency Austria, Spittelauer Lande5, ¨ AT-1090, Vienna, Austria.
    Elustondo, David
    University of Navarra, BIOMA Institute for Biodiversity and the Environment, Irunlarrea 1, 31008, Pamplona, Spain.
    Grandin, Ulf
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Holubová, Adéla
    Air Quality Department, Czech Hydrometeorological Institute, Koˇsetice Observatory, 394 24, Czech Republic.
    Kleemola, Sirpa
    Finnish Environment Institute, Latokartanonkaari 11, FI-00790, Helsinki, Finland.
    Krám, Pavel
    Department of Environmental Geochemistry and Biogeochemistry, Czech Geological Survey, Klarov ´ 3, CZ-11821, Prague, Czech Republic.
    Lundin, Lars
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Löfgren, Stefan
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Markensten, Hampus
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Moldan, Filip
    IVL Swedish Environmental Research Institute.
    Pihl Karlsson, Gunilla
    IVL Swedish Environmental Research Institute.
    Rönnback, Pernilla
    Department of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE-75007, Uppsala, Sweden.
    Valinia, Salar
    Ensucon AB, Sankt Eriksgatan 63B, 11234, Stockholm, Sweden.
    Vuorenmaa, Jussi
    Finnish Environment Institute, Latokartanonkaari 11, FI-00790, Helsinki, Finland.
    Trends in mercury, lead and cadmium concentrations in 27 European streams and rivers: 2000–20202024In: Environmental Pollution, ISSN 0269-7491, E-ISSN 1873-6424, Vol. 360, p. 124761-124761, article id 124761Article in journal (Refereed)
    Abstract [en]

    Temporal trends for concentrations of mercury (Hg), lead (Pb) and cadmium (Cd) were evaluated from year 2000–2020 in 20 (Hg), 23 (Pb) and 11 (Cd) watercourses in remote forest catchments in Europe. Decreasing trends were observed in 15% (Hg), 39% (Pb) and 45% (Cd) of the watercourses during the period of evaluation. Decreasing trends were mainly observed between 2000 and 2005 for Hg and between 2000 and 2015 for Pb and Cd. For the last five years of the studied time period (2015–2020), more watercourses showed significant increasing, rather than decreasing Hg, Pb and Cd trends.

    This was interpreted as a legacy effect of metals still retained in catchment soils. The overall negative trends during the earlier part of the study period were likely driven by declining deposition of metals over Europe, especially for Pb and Cd. Other changes related to metal transport and chemistry may have contributed to the observed trends as well, including recovery from acidification and the ongoing browning of surface waters at northern latitudes. Here we found that organic carbon could explain the seasonal variation in Hg and Pb, but was not related the interannual trends. This study highlights the need for long-term monitoring and robust statistical methods that can detect multidirectional, long-term change in water chemistry.

  • 4.
    Granberg, Maria
    et al.
    IVL Swedish Environmental Research Institute.
    Magnusson, Kerstin
    IVL Swedish Environmental Research Institute.
    Dahl, M.
    Bergman, S.
    Björk, M.
    Diaz-Almela, E.
    Gullström, M.
    Leiva-Dueñas, C.
    Marco-Mendés, C.
    Piñeiro-Juncal, N.
    Mateo, MA.
    A temporal record of microplastic pollution in Mediterranean seagrass soils2021In: Environmental Pollution, ISSN 0269-7491, E-ISSN 1873-6424, no 273, article id 116451Article in journal (Refereed)
    Abstract [en]

    Plastic pollution is emerging as a potential threat to the marine environment. In the current study, we selected seagrass meadows, known to efficiently trap organic and inorganic particles, to investigate the concentrations and dynamics of microplastics in their soil. We assessed microplastic contamination and accumulation in 210Pb dated soil cores collected in Posidonia oceanica meadows at three locations along the Spanish Mediterranean coast, with two sites located in the Almería region (Agua Amarga and Roquetas) and one at Cabrera Island (Santa Maria). Almería is known for its intense agricultural industry with 30 000 ha of plastic-covered greenhouses, while the Cabrera Island is situated far from urban areas. Microplastics were extracted using enzymatic digestion and density separation. The particles were characterized by visual identification and with Fourier-transformed infrared (FTIR) spectroscopy, and related to soil age-depth chronologies. Our findings showed that the microplastic contamination and accumulation was negligible until the mid-1970s, after which plastic particles increased dramatically, with the highest concentrations of microplastic particles (MPP) found in the recent (since 2012) surface soil of Agua Amarga (3819 MPP kg 1), followed by the top-most layers of the soil of the meadows in Roquetas (2173 kg 1) and Santa Maria (68e362 kg 1). The highest accumulation rate was seen in the Roquetas site (8832 MPP m 2 yr 1). The increase in microplastics in the seagrass soil was associated to land-use change following the intensification of the agricultural industry in the area, with a clear relationship between the development of the greenhouse industry in Almería and the concentration of microplastics in the historical soil record. This study shows a direct linkage between intense anthropogenic activity, an extensive use of plastics and high plastic contamination in coastal marine ecosystems such as seagrass meadows. We highlight the need of proper waste management to protect the coastal environment from continuous pollution.

  • 5.
    Magnusson, Kerstin
    et al.
    IVL Swedish Environmental Research Institute.
    Granberg, Maria
    IVL Swedish Environmental Research Institute.
    Piarulli, S.
    Scapinello, S.
    Comandini, P.
    X. W. Wong, J.
    Sciutto, G.
    Prati, S.
    Mazzeo, R.
    M. Booth, A.
    Airoldi, Rl
    Microplastic in wild populations of the omnivorous crab Carcinus aestuarii: A review and a regional-scale test of extraction methods, including microfibres.2019In: Environmental Pollution, ISSN 0269-7491, E-ISSN 1873-6424, Vol. 251, p. 117-127Article in journal (Refereed)
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