Research Progress on Pollution Situation and Remediation Technology of Perfluoroalkyl Substances in River Water

doi:10.16258/j.cnki.1674-5906.2023.12.004

Ecology and Environment ›› 2023, Vol. 32 ›› Issue (12): 2115-2127.DOI: 10.16258/j.cnki.1674-5906.2023.12.004

• Papers on “New Pollutants” • Previous Articles Next Articles

Research Progress on Pollution Situation and Remediation Technology of Perfluoroalkyl Substances in River Water

HAO Liyu¹(), HE Miaomiao², TANG Jiaxi¹^,³^,^*()

1. College of Environmental Science and Engineering, Liaoning Technical University, Fuxin 123000, P. R. China
2. College of Civil Engineering, Liaoning Technical University, Fuxin 123000, P. R. China
3. Liaoning Academy of Agricultural Sciences, Shenyang 110161, P. R. China

Received:2023-08-16 Online:2023-12-18 Published:2024-02-05
Contact: TANG Jiaxi

河流水体全氟化合物的污染现状及修复技术研究进展

郝丽宇¹(), 何苗苗², 汤家喜¹^,³^,^*()

1.辽宁工程技术大学环境科学与工程学院，辽宁阜新123000
2.辽宁工程技术大学土木工程学院，辽宁阜新123000
3.辽宁省农业科学研究院，辽宁沈阳 110161

通讯作者: 汤家喜
作者简介:郝丽宇（1997年生），女，硕士研究生，研究方向为环境污染与生态修复。E-mail: hly12345ssdlh@163.com
基金资助:
辽宁省应用基础研究计划项目(2022JH2/101300123);辽宁省百千万人才工程资助项目(2021921100)

Abstract

Abstract:

Perfluoroalkyl Substances (PFASs) are a novel class of environmental pollutants with unique structures. As synthetic persistent organic compounds, they have been widely utilized in fire protection, industry, and other fields, garnering global attention due to their persistence and toxic effects on the environment. PFASs exhibit resistance to natural degradation in the environment, and have certain hydrophilicity, thereby rendering river water a significant source and sink of PFASs, posing a threat to the water environment. In recent years, domestic and foreign scholars have studied and proposed a variety of remediation technologies to effectively mitigate the harmful impacts of PFASs on the environment and human health. The article provided a concise overview of the sources of PFASs. Fluorine chemical enterprises have been one of the important sources of PFASs in environmental media. The pollution status of PFASs in river water was analyzed. Both point and non-point sources contribute to the contamination. However, it is crucial to also address non-point source pollution, particularly the presence of colloid-loaded PFASs, which necessitates prompt resolution. The sources and pathways of PFASs migration in river water have been clarified, with industrial parks identified as the main sources of PFASs. The article further summarized physical and chemical remediation technologies employed in water environment (i.e., adsorption technology, filtration technology, chemical oxidation technology, photochemical oxidation technology, electrochemical oxidation technology, and sonochemical technology), compared and analyzed the advantages and disadvantages of different remediation technologies, and proposed future development directions. The remediation effects and mechanisms of in-situ remediation technology (e.g., riparian filtration system, phytoremediation technology, constructed wetland, and ecological buffer zone) for non-point source PFASs in the water environment were explored. Building upon these findings, a combined remediation approach incorporating biochar and ecological buffer zones was proposed to control non-point source pollution of PFASs in the water environment, and its potential was prospectively evaluated. The purpose of this article was to provide effective support and recommendations for the remediation technologies of PFASs in river water.

Key words: perfluoroalkyl substances (PFASs), river water, point source pollution, nonpoint source pollution, phytoremediation, ecological buffer zone

摘要：

全氟化合物（PFASs）是一类具有特殊结构的新型环境污染物，作为一种人工合成的持久性有机化合物，已被广泛应用于消防、工业等多领域，因其对环境的持久性和生物毒性而受到全球关注。PFASs在自然环境中不易降解，且具有一定的亲水性，导致河流水体成为了PFASs的重要的源和汇，对水环境造成了一定的危害。近年来，国内外学者研究并提出了多种有效去除PFASs的修复技术，以减轻其对环境和人体的有害影响。该文简述了PFASs的来源，氟化工企业是环境介质中PFASs的重要来源之一。分析了PFASs在河流水体中的污染现状，河流水体中PFASs的主要来源为点源和非点源，然而非点源污染，尤其是胶体载带PFASs的污染也应加以关注并亟待解决。阐明了河流水体中PFASs的来源与迁移途径，其中工业园区是PFASs的主要来源。该文还总结了水环境中PFASs的物理化学修复技术（吸附技术、过滤技术、化学氧化技术、光化学氧化技术，电化学氧化技术和声化学技术），并对比分析了不同修复技术作用效果的优缺点及未来的发展方向。重点探究了水环境中PFASs非点源的原位修复技术（河岸过滤系统、植物修复技术、人工湿地和生态缓冲带）的修复效果及作用机制。在此基础上，提出了生物炭与生态缓冲带联合修复技术，阻控水环境中PFASs非点源污染，并对其技术的潜力进行了展望。该文旨在为河流水体中PFASs的修复技术提供有效的支持和建议。

关键词: 全氟化合物, 河流水体, 点源污染, 非点源污染, 植物修复技术, 生态缓冲带

CLC Number:

HAO Liyu, HE Miaomiao, TANG Jiaxi. Research Progress on Pollution Situation and Remediation Technology of Perfluoroalkyl Substances in River Water[J]. Ecology and Environment, 2023, 32(12): 2115-2127.

郝丽宇, 何苗苗, 汤家喜. 河流水体全氟化合物的污染现状及修复技术研究进展[J]. 生态环境学报, 2023, 32(12): 2115-2127.

Figures/Tables 9

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名称	基本结构
PFOA 全氟辛酸
PFOS 全氟辛烷磺酸
PFNA 全氟壬二酸
PFDA 全氟癸酸
PFUnDA 全氟十一酸
PFDoDA 全氟十二烷酸
PFTrDA 全氟十三酸
PFTDA 全氟十四酸

名称	基本结构
PFOA 全氟辛酸
PFOS 全氟辛烷磺酸
PFNA 全氟壬二酸
PFDA 全氟癸酸
PFUnDA 全氟十一酸
PFDoDA 全氟十二烷酸
PFTrDA 全氟十三酸
PFTDA 全氟十四酸

流域	PFASs数量	质量浓度/(ng∙L⁻¹)			参考文献
流域	PFASs数量	∑PFASs	PFOS	PFOA	参考文献
印度南部流域	13	0.39‒3.32	0.19‒0.65	0.23‒1.06	Selvaraj et al., 2021
洛东江 (韩国)	12	0.22‒73.90	0.12‒33.20	0.12‒42.20	Lam et al., 2016b
易北河 (德国)	17	7.10‒27.60	0.50‒2.90	2.80‒9.60	Ahrens et al., 2009
布里斯班河 (澳大利亚)	7	0.83‒40.00	0.18‒15.00	0.13‒1.60	Gallen et al., 2014
红河 (越南)	10	4.00‒17.00	0.18‒5.30	0.09‒18.00	Duong et al., 2015
长江 (中国)	18	2.20‒174.56	0.23‒12.22	6.81‒15.61	Pan et al., 2014
黄河 (中国)	17	7.75‒121.63	0.95‒15.37	0.96‒14.15	Wang et al., 2014
珠江 (中国)	13	3.00‒52.00	0.71‒8.70	0.56‒11.00	Zhang et al., 2013
松花江 (中国)	15	6.40‒32.00	ND	ND‒1.70	Zhang et al., 2018b
海河 (中国)	9	12.00‒174.00	2.02‒17.62	14.40‒42.10	Li et al., 2011
大凌河 (中国)	11	1.77‒9540.00	0.16‒483.00	ND‒2280.00	Zhu et al., 2015
辽河 (中国)	11	44.40‒781.00	0.09‒9.50	0.67‒61.60	Chen et al., 2015

流域	PFASs数量	质量浓度/(ng∙L⁻¹)			参考文献
流域	PFASs数量	∑PFASs	PFOS	PFOA	参考文献
印度南部流域	13	0.39‒3.32	0.19‒0.65	0.23‒1.06	Selvaraj et al., 2021
洛东江 (韩国)	12	0.22‒73.90	0.12‒33.20	0.12‒42.20	Lam et al., 2016b
易北河 (德国)	17	7.10‒27.60	0.50‒2.90	2.80‒9.60	Ahrens et al., 2009
布里斯班河 (澳大利亚)	7	0.83‒40.00	0.18‒15.00	0.13‒1.60	Gallen et al., 2014
红河 (越南)	10	4.00‒17.00	0.18‒5.30	0.09‒18.00	Duong et al., 2015
长江 (中国)	18	2.20‒174.56	0.23‒12.22	6.81‒15.61	Pan et al., 2014
黄河 (中国)	17	7.75‒121.63	0.95‒15.37	0.96‒14.15	Wang et al., 2014
珠江 (中国)	13	3.00‒52.00	0.71‒8.70	0.56‒11.00	Zhang et al., 2013
松花江 (中国)	15	6.40‒32.00	ND	ND‒1.70	Zhang et al., 2018b
海河 (中国)	9	12.00‒174.00	2.02‒17.62	14.40‒42.10	Li et al., 2011
大凌河 (中国)	11	1.77‒9540.00	0.16‒483.00	ND‒2280.00	Zhu et al., 2015
辽河 (中国)	11	44.40‒781.00	0.09‒9.50	0.67‒61.60	Chen et al., 2015

修复技术	材料	过程	优缺点	参考文献
吸附	吸附材料 (活性炭、改性生物质、树脂等)	选用不同种类的吸附剂来吸附PFASs, 以达到去除的效果	去除效果好, 但操作维护成本高	Nzerib et al., 2019
过滤	过滤材料 (纳滤膜和反渗透膜等)	常用反渗透膜和纳滤膜分离PFASs	去除效果好, 操作简单, 但膜的替换与高质量浓度滞留液的处理会使成本增高	Rahman et al., 2014; Lee et al., 2022
高级氧化技术AOPs	氧化剂(过氧化氢、过硫酸钠、高锰酸钾、高锰酸钠、臭氧等)	使溶液中产生强氧化性的羟基-OH, 与溶液中的PFASs反应, 转化成为无毒可降解的副产物	反应速度慢, 成本高, 氧化过程中产生的短链PFASs可能造成二次污染, 可与其他方法结合使用	Park et al., 2016; Wu et al., 2018
光化学氧化技术	紫外线，可见光等	利用紫外线或可见光产生水合电子来去除PFASs	绿色环保, 可减少二次污染, 但效率低, 成本高, 无法大规模使用	Chen et al., 2016
电化学氧化技术	电极 (石墨烯, 二氧化铅、氧化钛、二氧化锡等)	通过直接或间接阳极氧化, 将PFASs吸附在电极上, 被电极直接降解, 或与其他液体反应进行降解	去除效率高, 反应时间短, 但反应过程中会产生短链PFASs和有毒副产物, 成本高	Wang et al., 2022
声化学技术	超声辐射	高级氧化处理的一种, 利用超声波辐照形成高温气泡与氧化性强的物质来降解PFASs	无法大规模使用, 成本高，受外界影响因素多 (如溶液pH、黏滞系数、表面张力系数、溶液温度等)	Dorrance et al., 2017; Mahinroosta et al., 2020

Research Progress on Pollution Situation and Remediation Technology of Perfluoroalkyl Substances in River Water

河流水体全氟化合物的污染现状及修复技术研究进展

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