Fast microplastics identification with stimulated Raman scattering microscopy

Fast microplastics identification with stimulated Raman scattering microscopy

The abundance of plastic products in modern society has resulted in a proliferation of small plastic particles called “microplastics” in the global environment. Currently, spectroscopic techniques such as Fourier‐transform infrared and spontaneous (i.e., conventional) Raman spectroscopy are widely e...

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Bibliographic Details
Published in:Journal of Raman spectroscopy Vol. 49; no. 7; pp. 1136 - 1144
Main Authors: Zada, Liron, Leslie, Heather A., Vethaak, A. Dick, Tinnevelt, Gerjen H., Jansen, Jeroen J., Boer, Johannes F., Ariese, Freek
Format: Journal Article
Language:English
Published: Bognor Regis Wiley Subscription Services, Inc 01-07-2018
Subjects:
Aluminum oxide
Calibration
Coherent scattering
Crosstalk
environment
Environmental monitoring
Estuaries
Estuarine environments
Fourier transforms
Image acquisition
Image filters
imaging
Laser beams
Microparticles
Microplastics
Microscopy
Molecular chains
Particulates
Plastic debris
Plastics
pollution
Polyethylene
Polyethylene terephthalate
Polymers
Raman spectra
Raman spectroscopy
Sediment samplers
spectroscopy
SRS
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Summary:The abundance of plastic products in modern society has resulted in a proliferation of small plastic particles called “microplastics” in the global environment. Currently, spectroscopic techniques such as Fourier‐transform infrared and spontaneous (i.e., conventional) Raman spectroscopy are widely employed for the identification of the plastic microparticles, but these are rather time consuming. Stimulated Raman scattering (SRS) microscopy, based on the coherent interaction of 2 different laser beams with vibrational levels in the molecules of the sample, would enable much faster detection and identification of microplastics. Here, we present for the first time an SRS‐based method for identifying 5 different high production‐volume polymer types in microplastics extracted from environmental or consumer product samples. The particles from the extracts were collected on a flat alumina filter, and 6 SRS images were acquired at specifically chosen wavenumbers. Next, we decomposed these spectral data into specific images for the 5 polymers selected for calibration. We tested the approach on an artificial mixture of plastic particles and determined the signal‐to‐noise and level of cross talk for the 5 polymer types. As a proof of principle, we identified polyethylene terephthalate particles extracted from a commercial personal care product, demonstrating also the thousand‐fold higher speed of mapping with SRS compared with conventional Raman. Furthermore, after density separation of a Rhine estuary sediment sample, we scanned 1 cm2 of the filter surface in less than 5 hr and detected and identified 88 microplastics, which corresponds to 12,000 particles per kilogram dry weight. We conclude that SRS can be an efficient method for monitoring microplastics in the environment and potentially many other matrices of interest. Stimulated Raman scattering (SRS) microscopy was developed for the fast detection and identification of microplastic pollution, a growing environmental problem. SRS was carried out at 6 specific wavenumbers for identifying 5 major polymer types. The image shows the SRS identification on a filter of several microplastics extracted from a Rhine estuary sediment; the inset is a particle identified as polystyrene. The approach offers a thousand‐fold higher mapping speed compared with conventional Raman spectroscopy.
ISSN:0377-0486
1097-4555
DOI:10.1002/jrs.5367