水体中纳米颗粒检测的研究进展

doi:10.3964/j.issn.1000-0593(2017)04-1021-06

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摘要：纳米颗粒在工业和化妆品等行业中的大规模应用，致使大量纳米颗粒进入水环境中，不可避免的产生了一系列的环境问题，同时对生物和人体造成不良影响，因此水环境中纳米颗粒的富集及其检测技术受到广泛关注。目前，多种技术可对水环境中痕量纳米颗粒浓度等特征进行检测，但其在灵敏度和精度方面均存在一定局限性。归纳了目前水环境中纳米颗粒的预处理技术，如超滤分离技术、色谱分离技术、固相萃取技术及浊点萃取技术；综述常用的纳米颗粒与离子检测技术，如光谱分析技术、电感耦合等离子质谱技术及电化学技术。通过对各种方法进行对比分析，使纳米颗粒预处理及检测技术能够被系统广泛的认识。并在此基础上对纳米颗粒的预处理及检测技术的发展前景进行了展望。

关键词：水环境；纳米颗粒检测；纳米颗粒预处理；光谱分析技术

Abstract：With the broad application of nanomaterials in cosmetics and other industries, the more and more nanoparticles have been released into the aquatic environment, which leads to a number of inevitable environmental issues. At the same time, they cause a negative effect on all kinds of organism including human being. Hence, the enrichment and detection technologies of nanoparticles in water have attracted more and more attention. Currently, a variety of technologies can be used to detect the concentration of trace nanoparticles, but they all have certain limitations in sensitivity and accuracy. In this paper, the pretreatment techniques such as ultrafiltration, chromatography, solid phase extraction, and cloud point extraction of nanoparticles in aquatic environment are generalized. The common detection techniques of nanoparticles, such as spectrum technology, the inductively coupled with plasma mass spectrometry and electrochemical detection techniques are summarized. Moreover, the further development prospects of pretreatment and detection technologies of nanoparticles are also discussed.

Key words：Water environment; Nanoparticles detection; Nanoparticles pretreatment; Spectrum technology

收稿日期: 2016-05-06 修订日期: 2016-10-05

中图分类号:

X132

基金资助: 国家自然科学基金青年科学基金项目(51308563)，2014年中央高校基本科研业务费项目(106112014CDJZR210004)，大型仪器基金项目(201406150031)资助

作者简介: 赵纯，1982年生，重庆大学城市建设与环境工程学院副教授 e-mail：pureson@163.com；pureson@cqu.edu.cn

引用本文:

赵纯，张轩，孙志华，杨广，朱云华，司斌，郑怀礼. 水体中纳米颗粒检测的研究进展[J]. 光谱学与光谱分析, 2017, 37(04): 1021-1026.
ZHAO Chun, ZHANG Xuan, SUN Zhi-hua, YANG Guang, ZHU Yun-hua, SI Bin, ZHENG Huai-li. Research Progress of Detection for Nanoparticles in Water. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2017, 37(04): 1021-1026.

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