对使用拉曼光谱法进行海洋微塑料视觉识别以改进分析的批判性评估。

A critical assessment of visual identification of marine microplastic using Raman spectroscopy for analysis improvement.

作者信息

Lenz Robin, Enders Kristina, Stedmon Colin A, Mackenzie David M A, Nielsen Torkel Gissel

机构信息

National Institute of Aquatic Resources, Technical University of Denmark, DTU, Kavalergården 6, 2920 Charlottenlund, Denmark.

出版信息

Mar Pollut Bull. 2015 Nov 15;100(1):82-91. doi: 10.1016/j.marpolbul.2015.09.026. Epub 2015 Oct 9.

DOI:10.1016/j.marpolbul.2015.09.026

PMID:26455785

Abstract

Identification and characterisation of microplastic (MP) is a necessary step to evaluate their concentrations, chemical composition and interactions with biota. MP ≥10μm diameter filtered from below the sea surface in the European and subtropical North Atlantic were simultaneously identified by visual microscopy and Raman micro-spectroscopy. Visually identified particles below 100μm had a significantly lower percentage confirmed by Raman than larger ones indicating that visual identification alone is inappropriate for studies on small microplastics. Sixty-eight percent of visually counted MP (n=1279) were spectroscopically confirmed being plastic. The percentage varied with type, colour and size of the MP. Fibres had a higher success rate (75%) than particles (64%). We tested Raman micro-spectroscopy applicability for MP identification with respect to varying chemical composition (additives), degradation state and organic matter coating. Partially UV-degraded post-consumer plastics provided identifiable Raman spectra for polymers most common among marine MP, i.e. polyethylene and polypropylene.

摘要

微塑料（MP）的识别与表征是评估其浓度、化学成分以及与生物群相互作用的必要步骤。从欧洲和亚热带北大西洋海面以下过滤出的直径≥10μm的微塑料，通过视觉显微镜和拉曼显微光谱法同时进行识别。通过视觉识别出的直径小于100μm的颗粒，经拉曼光谱法确认的比例明显低于较大颗粒，这表明仅靠视觉识别不适用于对小微塑料的研究。通过视觉计数的微塑料中（n = 1279），68%经光谱学确认是塑料。该比例随微塑料的类型、颜色和尺寸而变化。纤维的成功率（75%）高于颗粒（64%）。我们针对不同的化学成分（添加剂）、降解状态和有机物涂层，测试了拉曼显微光谱法在微塑料识别中的适用性。部分经紫外线降解的消费后塑料为海洋微塑料中最常见的聚合物，即聚乙烯和聚丙烯，提供了可识别的拉曼光谱。

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对使用拉曼光谱法进行海洋微塑料视觉识别以改进分析的批判性评估。

A critical assessment of visual identification of marine microplastic using Raman spectroscopy for analysis improvement.

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