Abstract:With the development of the plastic industry, microplastic, which is difficult to degrade in nature, became one of the main environmental pollutants. Moreover, it harms human health as it accumulates within the organisms and environment. Therefore, the detection and assessment of microplastics in the environment have been highly concern in recent years. Most the works first extract microplastics from samples by flotation, density or centrifugation separation system, and then find the microplastics under a microscope directly or combine with Raman spectroscopy, Fourier Transform infrared spectroscopy, Hyperspectral imaging and other methods for analysis and identification. Nonetheless, these methods require a long waiting time for pretreatment and could easily be affected by subjective factors. To identify whether the microplastics are in environmental samples or not quickly and accurately, we propose to use the multi-channel image acquisition, including white light channel imaging and Coherent Anti-stokes Raman Scattering (CARS) spectral imaging. CARS spectral imaging is a non-invasive and non-destructive real-time imaging method based on chemical bond vibration. Microplastic with a diameter of 10 μm polluted seawater and sand were simulated by the collected seawater/sand mixing with polystyrene microspheres. We detected the distribution of polystyrene in seawater intuitively through multi-channels image acquisition. The multi-channel image of polystyrene microspheres in the sand was collected and compared with the image by Raman spectroscopy. In the detection of Raman spectroscopy, the signal of polystyrene microspheres is easily interfered with by the fluorescence signal of sand, and only when the laser is focused on the location of polystyrene, does the weak signal can be detected. In the multi-channel image acquisition and detection, polystyrene microspheres can be seen in the sand, and we used a simple morphological analysis and filtering algorithm to make the microplastic signal obvious. Multi-channels image acquisition for microplastics detecting (in seawater and sand) without pretreatment is fast and simple, which has a certain potential for detecting microplastics in the environment value.
焦若男,刘 琨,孔繁艺,王 婷,韩 雪,李泳江,孙长森. 近海微塑料含量的相干反斯托克斯拉曼光谱成像研究[J]. 光谱学与光谱分析, 2022, 42(04): 1022-1027.
JIAO Ruo-nan, LIU Kun, KONG Fan-yi, WANG Ting, HAN Xue, LI Yong-jiang, SUN Chang-sen. Research on Coherent Anti-Stokes Raman Spectroscopy Detection of
Microplastics in Seawater and Sand. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(04): 1022-1027.
[1] Zhao J, Ran W, Teng J, et al. Science of the Total Environment, 2018, 640: 637.
[2] de Haan W P, Sanchez-Vidal A, Canals M, et al. Marine Pollution Bulletin, 2019, 140: 523.
[3] Cincinelli A, Scopetani C, Chelazzi D, et al. Chemosphere, 2017, 175: 391.
[4] Geilfus N, Munson K M, Sousa J, et al. Marine Pollution Bulletin, 2019, 145: 463.
[5] Collicutt B, Juanes F, Dudas S E. Environmental Pollution, 2019, 244: 135.
[6] Hernandez-Gonzalez A, Saavedra C, Gago J, et al. Marine Pollution Bulletin, 2018, 137: 526.
[7] Karbalaei S, Hanachi P, Walker T R, et al. Environmental Science and Pollution Research, 2018, 25(36SI): 36046.
[8] Huang B, Sun L, Liu M, et al. Environmental Science and Pollution Research, 2020, 28(2): 1675.
[9] Panebianco A, Nalbone L, Giarratana F, et al. Food Control, 2019, 106(UNSP 106722): 106722.
[10] Scanes E, Wood H, Ross P. Marine Pollution Bulletin, 2019, 149: 110537.
[11] Karlsson T M, Vethaak A D, Almroth B C, et al. Marine Pollution Bulletin, 2017, 122(1-2): 403.
[12] Hermsen E, Pompe R, Besseling E, et al. Marine Pollution Bulletin, 2017, 122(1-2): 253.
[13] Dodson G Z, Shotorban A K, Hatcher P G, et al. Marine Pollution Bulletin, 2020, 151: 110869.
[14] Zhang S, Yang X, Gertsen H, et al. Science of the Total Environment, 2018, 616: 1056.
[15] HOU Guo-hui,CHEN Bing-ling,LUO Teng, et al(侯国辉,陈秉灵,罗 腾, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2018, 38(2): 606.
