Publications

Mikrosensorer - på vei fra leketøy til anerkjent verktøy.

Høiskar, B. A. K.

Mikroplast og PFAS er giftigere sammen enn hver for seg

Schmidt, Natascha (interview subject); Bergstrøm, Ida Irene (journalist)

Mikroplast fra trafikken havner i Arktis

Evangeliou, Nikolaos; Grythe, Henrik (interview subjects); Dæhlen, Marte (journalist)

Migration analysis of chemical additives from indoor consumer plastic products

Bohlin-Nizzetto, Pernilla

NILU has, on behalf of the Norwegian Environment Agency, performed chemical analyses of a selection of chemical additives in indoor consumer plastic products. The goal was to identify content and migration of the chemical additives in and from the products to particles and surfaces of the products at room temperature. The plastic products included; furniture wrap, wall papers, table cloths, shower curtains, floor tiles, mattresses, pillows, carpet underlays and a bathtub mat. Targeted chemicals were organophosphorous flame retardants (OPFRs), brominated flame retardants (BFRs) including tetrabromobisphenol A (TBBPA), chlorinated paraffins (CPs) and dechloranes. MCCPs and SCCPs were found in ‰ to % levels in PVC containing products. Four of the OPFRs were found in up to ‰ levels in adhesive foils to be put on furniture or floor/walls and mattresses. None of the targeted brominated compounds nor melamine were detected in the product samples.

NILU

Microwave satellite remote sensing of soil moisture

Blyverket, Jostein; Hamer, Paul; Lahoz, William A.

Microplastics in the atmosphere and cryosphere in the circumpolar North: a case for multicompartment monitoring

Hamilton, Bonnie M.; Jantunen, Liisa; Bergmann, Melanie; Vorkamp, Katrin; Aherne, Julian; Magnusson, Kerstin; Herzke, Dorte; Granberg, Maria; Hallanger, Ingeborg G.; Gomiero, Alessio; Peeken, Ilka

The atmosphere and cryosphere have recently garnered considerable attention due to their role in transporting microplastics to and within the Arctic, and between freshwater, marine, and terrestrial environments. While investigating either in isolation provides valuable insight on the fate of microplastics in the Arctic, monitoring both provides a more holistic view. Nonetheless, despite the recent scientific interest, fundamental knowledge on microplastic abundance and consistent monitoring efforts are lacking for these compartments. Here, we build upon the work of the Arctic Monitoring and Assessment Programme's Monitoring Guidelines for Litter and Microplastic to provide a roadmap for multicompartment monitoring of the atmosphere and cryosphere to support our understanding of the sources, pathways, and sinks of plastic pollution across the Arctic. Overall, we recommend the use of existing standard techniques for ice and atmospheric sampling and to build upon existing monitoring efforts in the Arctic to obtain a more comprehensive pan-Arctic view of microplastic pollution in these two compartments.

Microplastics in the Arctic and Mainland Norway; Occurence, Composition and Sources

Evangeliou, Nikolaos; Herzke, Dorte; Schmidt, Natascha; Schulze, Dorothea; Eckhardt, Sabine

Microplastics in Norwegian coastal areas, rivers, lakes and air (MIKRONOR1)

Bavel, Bert van; Lusher, Amy Lorraine; Consolaro, Chiara; Hjelset, Sverre; Singdahl-Larsen, Cecilie; Buenaventura, Nina Tuscano; Röhler, Laura; Pakhomova, Svetlana; Lund, Espen; Eidsvoll, David; Herzke, Dorte; Bråte, Inger Lise Nerland

The Norwegian Environment Agency (Miljødirektoratet, NEA) tasked the Norwegian Institute for Water Research (NIVA) to initiate Norway’s National microplastic monitoring program. The program “Microplastics in Norwegian coastal areas, rivers, lakes and air (MIKRONOR)”, was designed to target the multitude of environments in the Norwegian coastal, freshwater and terrestrial ecosystems. The primary aim is to provide information on levels and types of microplastics in aquatic environments as well as in air and build on the baseline data already generated for a number of these environments on previous assignments by NEA.
This report contains the first results of coastal sites, open marine waters, lakes, rivers and air including high-volume water samples (freshwater and marine, n=48), Ferrybox samples (marine, n=20), blue mussels (marine, n=71), vertical plankton net samples (marine, n=29) and 24 air samples (precipitation n= 12 and active air sampling n = 12).

Norsk institutt for vannforskning (NIVA)

Microplastics in Norwegian coastal areas, rivers, lakes and air (MIKRONOR)

Bavel, Albert Van; Consolaro, Chiara; Singdahl-Larsen, Cecilie; Hjelset, Sverre; Pakhomova, Svetlana; Lund, Espen; Herzke, Dorte; Röhler, Laura; Hjermann, Dag Øystein; Lusher, Amy Lorraine

Microplastics catch an atmospheric ride to the oceans and the Arctic

Evangeliou, Nikolaos (interview subject); Bourzac, Katherine (journalist)

Microplastic to be measured at EMEP sites in the frame of MAGIC project

Evangeliou, Nikolaos; Yttri, Karl Espen; Herzke, Dorte; Cassiani, Massimo; Eckhardt, Sabine; Kylling, Arve; Wisthaler, Armin; Stohl, Andreas; Tichy, Ondrej; Revell, Laura E.

Microplastic pellets in Arctic marine sediments: a common source or a common process?

Collard, France; Hallanger, Ingeborg G.; Philipp, Carolin; Herzke, Dorte; Schmidt, Natascha; Hotvedt, Ådne; Galtung, Kristin; Rydningen, Tom Arne; Litti, Lucio; Gentili, Giulia; Husum, Katrine

Plastic consumption is increasing, and millions of tonnes of plastic are released into the oceans every year. Plastic materials are accumulating in the marine environment, especially on the seafloor. The Arctic is contaminated with plastics, including microplastics (MPs, <5 mm) but occurrences, concentrations and fate are largely unknown. This study aimed at assessing whether MPs accumulate at greater water depths in the Barents Sea, and close to the Longyearbyen settlement, and at understanding the ubiquity and source of a specific type of collected pellets. Surface sediments were collected at seven stations around Svalbard with a box-corer, and three replicates were taken at each station. MPs were extracted through density separation with saturated saltwater. Many pellets were found, and their composition was assessed by pyrolysis-GC/MS. Procedural blanks were performed using field blanks as samples to assess the overall contamination. The composition of all extracted particles was then analysed by μRaman spectroscopy. On average, 3.61 ± 1.45 MPs/100 g (dw) were found. The sea ice station, after blank correction, was more contaminated and displaying a different profile than the other stations, and the deepest station did not show the highest MP concentrations but rather the opposite. Sediments close to Longyearbyen were not more contaminated than the other stations either. Dark pellets of similar aspect were found at all stations, raising the question about a possible common source or process. These pellets were made of several plastic polymers which varied in proportion for each pellet, suggesting a common process was at the origin of those pellets, potentially marine snow formation.