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Microplastic concentrations, size distribution, and polymer types in the surface waters of a northern European lake
Water Environment Research2019
216 citations
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Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 45
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0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Emilia Uurasjärvi,
Outi Setälä
Emilia Uurasjärvi,
Outi Setälä
Outi Setälä
Emilia Uurasjärvi,
Outi Setälä
Emilia Uurasjärvi,
Arto Koistinen,
Outi Setälä
Outi Setälä
Maiju Lehtiniemi,
Emilia Uurasjärvi,
Maiju Lehtiniemi,
Emilia Uurasjärvi,
Samuel Hartikainen,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Outi Setälä
Samuel Hartikainen,
Samuel Hartikainen,
Outi Setälä
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Samuel Hartikainen,
Samuel Hartikainen,
Samuel Hartikainen,
Samuel Hartikainen,
Samuel Hartikainen,
Samuel Hartikainen,
Samuel Hartikainen,
Samuel Hartikainen,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Outi Setälä
Outi Setälä
Arto Koistinen,
Outi Setälä
Outi Setälä
Arto Koistinen,
Outi Setälä
Outi Setälä
Outi Setälä
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Outi Setälä
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Arto Koistinen,
Emilia Uurasjärvi,
Samuel Hartikainen,
Maiju Lehtiniemi,
Outi Setälä
Outi Setälä
Maiju Lehtiniemi,
Outi Setälä
Arto Koistinen,
Maiju Lehtiniemi,
Outi Setälä
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Arto Koistinen,
Emilia Uurasjärvi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Arto Koistinen,
Arto Koistinen,
Maiju Lehtiniemi,
Arto Koistinen,
Arto Koistinen,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Emilia Uurasjärvi,
Outi Setälä
Arto Koistinen,
Arto Koistinen,
Emilia Uurasjärvi,
Maiju Lehtiniemi,
Outi Setälä
Arto Koistinen,
Arto Koistinen,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Outi Setälä
Outi Setälä
Samuel Hartikainen,
Arto Koistinen,
Arto Koistinen,
Maiju Lehtiniemi,
Samuel Hartikainen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Maiju Lehtiniemi,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Arto Koistinen,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Emilia Uurasjärvi,
Maiju Lehtiniemi,
Arto Koistinen,
Outi Setälä
Maiju Lehtiniemi,
Arto Koistinen,
Outi Setälä
Summary
Microplastics were detected in surface waters of a northern European lake, with concentrations, size distributions, and polymer types characterized across multiple sampling sites and seasons. The study adds to growing evidence that even relatively pristine boreal lakes are contaminated with microplastics, likely from atmospheric deposition and tributary inflow.
We examined microplastic concentrations, size distributions, and polymer types in surface waters of a northern European dimictic lake. Two sampling methods, a pump sieving water onto filters with different pore sizes (20, 100, and 300 µm) and a common manta trawl (333 µm), were utilized to sample surface water from 12 sites at the vicinity of potential sources for microplastic emissions. The number and polymer types of microplastics in the samples were determined with optical microscopy and μFTIR spectroscopy. The average concentrations were 0.27 ± 0.18 (mean ± SD) microplastics/m<sup>3</sup> in manta trawled samples and 1.8 ± 2.3 (>300 μm), 12 ± 17 (100-300 μm) and 155 ± 73 (20-100 μm) microplastics/m<sup>3</sup> in pump filtered samples. The majority (64%) of the identified microplastics (n = 168) were fibers, and the rest were fragments. Materials were identified as polymers commonly used in consumer products, such as polyethylene, polypropylene, and polyethylene terephthalate. Microplastic concentrations were high near the discharge pipe of a wastewater treatment plant, harbors, and snow dumping site. PRACTITIONER POINTS: Samples were taken with a manta trawl (333 μm) and a pump filtration system (300/100/20 μm) With pump filtration, small 20-300 μm particles were more common than >300 μm particles The average concentration of manta trawled samples was 0.27 ± 0.18 (mean ± SD) microplastics/m<sup>3</sup> FTIR analysis revealed PE, PP, PET, and PAN to be the most common polymers.