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Micro- and Nanoplastics in Alpine Snow: A New Method for Chemical Identification and (Semi)Quantification in the Nanogram Range

Environmental Science & Technology 2020 329 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 60 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Daniela Kau, Daniela Kau, Erik van Sebille Dušan Materić, Erik van Sebille Erik van Sebille Erik van Sebille Dušan Materić, Erik van Sebille Dušan Materić, Dušan Materić, Erik van Sebille Dušan Materić, Dušan Materić, Erik van Sebille Dušan Materić, Erik van Sebille Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Erik van Sebille Erik van Sebille Erik van Sebille Marnick Anten, Erik van Sebille Marnick Anten, Erik van Sebille Erik van Sebille Erik van Sebille Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Dušan Materić, Rupert Holzinger, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Elke Ludewig, Elke Ludewig, Elke Ludewig, Anne Kasper‐Giebl, Thomas Röckmann, Thomas Röckmann, Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Rupert Holzinger, Erik van Sebille Dušan Materić, Dušan Materić, Dušan Materić, Rupert Holzinger, Rupert Holzinger, Rupert Holzinger, Rupert Holzinger, Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Daniela Kau, Thomas Röckmann, Rupert Holzinger, Rupert Holzinger, Rupert Holzinger, Erik van Sebille Erik van Sebille Erik van Sebille Anne Kasper‐Giebl, Erik van Sebille Rupert Holzinger, Erik van Sebille Erik van Sebille Erik van Sebille Rupert Holzinger, Rupert Holzinger, Dušan Materić, Marnick Anten, Erik van Sebille Erik van Sebille Erik van Sebille Rupert Holzinger, Marnick Anten, Erik van Sebille Thomas Röckmann, Rupert Holzinger, Rupert Holzinger, Dušan Materić, Rupert Holzinger, Erik van Sebille Erik van Sebille Rupert Holzinger, Rupert Holzinger, Erik van Sebille Rupert Holzinger, Dušan Materić, Marion Greilinger, Rupert Holzinger, Dušan Materić, Erik van Sebille Dušan Materić, Thomas Röckmann, Anne Kasper‐Giebl, Erik van Sebille Marion Greilinger, Thomas Röckmann, Erik van Sebille Erik van Sebille Anne Kasper‐Giebl, Dušan Materić, Erik van Sebille Erik van Sebille Dušan Materić, Rupert Holzinger, Dušan Materić, Dušan Materić, Dušan Materić, Rupert Holzinger, Rupert Holzinger, Erik van Sebille Elke Ludewig, Rupert Holzinger, Erik van Sebille Erik van Sebille Anne Kasper‐Giebl, Rupert Holzinger, Erik van Sebille Rupert Holzinger, Thomas Röckmann, Erik van Sebille Erik van Sebille Thomas Röckmann, Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Erik van Sebille Thomas Röckmann, Dušan Materić, Dušan Materić, Dušan Materić, Erik van Sebille Dušan Materić, Erik van Sebille Dušan Materić, Thomas Röckmann, Dušan Materić, Rupert Holzinger, Rupert Holzinger, Rupert Holzinger, Erik van Sebille Thomas Röckmann, Rupert Holzinger, Erik van Sebille Erik van Sebille Erik van Sebille Thomas Röckmann, Erik van Sebille Erik van Sebille Erik van Sebille Dušan Materić, Erik van Sebille Erik van Sebille

Summary

Researchers developed a highly sensitive new method for detecting micro- and nanoplastics using thermal desorption mass spectrometry, achieving detection limits 100 times better than previous techniques. They used this method to identify multiple types of plastic particles in snow samples from the Austrian Alps, including nanometer-scale polyethylene terephthalate. The presence of nanoplastics in high-altitude alpine snow confirms that plastic pollution travels through the atmosphere to even remote locations.

Polymers

PE PET PP PS PVC

We present a new method for chemical characterization of micro- and nanoplastics based on thermal desorption-proton transfer reaction-mass spectrometry. The detection limit for polystyrene (PS) obtained is <1 ng of the compound present in a sample, which results in 100 times better sensitivity than those of previously reported by other methods. This allows us to use small volumes of samples (1 mL) and to carry out experiments without a preconcentration step. Unique features in the high-resolution mass spectrum of different plastic polymers make this approach suitable for fingerprinting, even when the samples contain mixtures of other organic compounds. Accordingly, we got a positive fingerprint of PS when just 10 ng of the polymer was present within the dissolved organic matter of snow. Multiple types of microplastics (polyethylene terephthalate (PET), polyvinyl chloride, and polypropylene carbonate), were identified in a snowpit from the Austrian Alps; however, only PET was detected in the nanometer range for both snowpit and surface snow samples. This is in accordance with other publications showing that the dominant form of airborne microplastics is PET fibers. The presence of nanoplastics in high-altitude snow indicates airborne transport of plastic pollution with environmental and health consequences yet to be understood.

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