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Analytics of paints and coatings with (reactive) pyrolysis-GC/MS – challenges and perspective

Zenodo (CERN European Organization for Nuclear Research) 2024 Score: 35 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Elena Hengstmann, Elena Hengstmann, Elena Hengstmann, Elena Hengstmann, Elena Hengstmann, Elena Hengstmann, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Marten Fischer Lars Hildebrandt, Marten Fischer Lars Hildebrandt, Lars Hildebrandt, Marten Fischer Lars Hildebrandt, Marten Fischer Marten Fischer Marten Fischer Marten Fischer Marten Fischer Lars Hildebrandt, Marten Fischer Tristan Zimmermann, Marten Fischer Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Torben Kirchgeorg, Elena Hengstmann, Elena Hengstmann, Elena Hengstmann, Elena Hengstmann, Elena Hengstmann, Marten Fischer Marten Fischer Marten Fischer Marten Fischer Marten Fischer Marten Fischer Marten Fischer Tristan Zimmermann, Tristan Zimmermann, Tristan Zimmermann, Tristan Zimmermann, Lars Hildebrandt, Tristan Zimmermann, Daniel Pröfrock, Lars Hildebrandt, Lars Hildebrandt, Tristan Zimmermann, Tristan Zimmermann, Tristan Zimmermann, Lars Hildebrandt, Lars Hildebrandt, Ole Klein, Tristan Zimmermann, Lars Hildebrandt, Lars Hildebrandt, Elena Hengstmann, Tristan Zimmermann, Lars Hildebrandt, Marten Fischer Ole Klein, Daniel Pröfrock, Ole Klein, Daniel Pröfrock, Tristan Zimmermann, Ole Klein, Lars Hildebrandt, Ole Klein, Daniel Pröfrock, Ole Klein, Lars Hildebrandt, Daniel Pröfrock, Marten Fischer Ole Klein, Ole Klein, Daniel Pröfrock, Tristan Zimmermann, Lars Hildebrandt, Lars Hildebrandt, Lars Hildebrandt, Ole Klein, Ole Klein, Tristan Zimmermann, Tristan Zimmermann, Tristan Zimmermann, Zonderman Alexa, Marten Fischer Zonderman Alexa, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Zonderman Alexa, Zonderman Alexa, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Lars Hildebrandt, Lars Hildebrandt, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Torben Kirchgeorg, Elena Hengstmann, Torben Kirchgeorg, Ole Klein, Torben Kirchgeorg, Ole Klein, Tristan Zimmermann, Daniel Pröfrock, Tristan Zimmermann, Tristan Zimmermann, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Daniel Pröfrock, Torben Kirchgeorg, Lars Hildebrandt, Daniel Pröfrock, Lars Hildebrandt, Daniel Pröfrock, Lars Hildebrandt, Lars Hildebrandt, Marten Fischer

Summary

Researchers examined the application of reactive pyrolysis-GC/MS as an analytical method for detecting and quantifying paint and coating particles in environmental samples, addressing challenges posed by the complex, layered structure of paint particles containing multiple polymers, pigments, and fillers. They found pyrolysis-GC/MS to be a promising approach for this difficult-to-analyze microplastic category, which one major estimate suggests may be the single largest global source of marine microplastics.

Study Type Environmental

Paints and coatings have recently become the focus of microplastics research, as a study has estimated high particle emissions of this type of microplastic1. For oceans and waterways, this study even estimates that paints and coatings are by far the largest source of microplastics. However, there is little environmental data on the concentration of paint and coating particles in sediment and water samples to confirm this study. One of the reasons for the lack of environmental data is that these particles are quite difficult to analyze. There are many different types of paints and coatings, each consisting of a complex formulation of different polymers, pigments, additives and fillers. The layered structure of the paint and coating particles, to which rust often still adheres, makes analysis with spectroscopic or visual methods difficult. I. A promising tool for the analysis of paint and coating particles in environmental samples is (reactive) pyrolysis gas chromatography/mass spectrometry (py-GC/MS). Based on this technique we will present: A mass-spectral database and a semi-automated data evaluation to achieve reliable identification of different paint types at the polymer level by py-GC/MS on the basis of the analysis of more than 40 corrosion protection coatings and 10 anti-fouling coatings. II. A proof-of-concept for the identification and quantification of antifouling paint particles (APPs) carried out for samples from underwater cleaning of ship hulls, for which ships with hard coatings, foul-release coatings (FR) and self-polishing coatings (SPC) were selected. III. A method comparison of py-GC/MS with spectroscopic techniques (laser direct infrared, RAMAN- and Fourier-transform infrared spectroscopy) carried out for 28 different single corrosion-protection coating particles. The comparison shows that py-GC/MS (in combination with multivariate statistics) is a well-suited tool for identification of paint and coating particles. 1Paruta, P., Pucino, M., & Boucher, J. (2022). Plastic Paints the Environment. https://www.e-a.earth/_files/ugd/425198_a864877fefd74ade85d85080ae21e029.pdf Also see: https://micro2024.sciencesconf.org/558784/document

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