Simultaneous removal of Microcystis aeruginosa and microplastics by oxidation enhanced coagulation

IF 7.6 2区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Environmental Pollution Pub Date : 2024-12-17 DOI:10.1016/j.envpol.2024.125555
Wenjun Du, Xin Xu, Lili An, Feng Yan, J Paul Chen, Ruihua Dai
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Abstract

The composite pollution is an increasingly severe challenge in the field of water treatment. Especially, microplastics (MPs) contamination and Microcystis aeruginosa (M. aeruginosa) were verified that they could synergistically pose a serious threat to safety of drinking water. Therefore, developing effective removal technology is an urgent task. In this study, the simultaneous removal of M. aeruginosa and polystyrene (PS, a typical plastic matter) was investigated by H2O2 enhanced Fe(II) coagulation. The results demonstrated that the removal rate of both algae and PS can reach over 90%. It was also demonstrated that the PS removal efficiency increased from 23.3% to 97.3% with the increase of M. aeruginosa biomass from 0 cells/mL to 0.5×106 cells/mL. The possible reason might be that the addition of algal cells raises the number of contaminant particles, which greatly increases the floc size during the coagulation process. It makes MPs easier to be trapped by sweep flocculation in this process. Additionally, naturally weathered polystyrene (NWPS) exhibited higher removal rate than virgin PS, due to more original functional groups, larger particle size (d50 9.75 μm to 11.25 μm), and a lower absolute zeta potential (-34.15 mV to -30.1 mV). Furthermore, low Fe residue level and AOM (algal organic matter) control was simultaneously achieved in this process (TOC < 1 mg/L, MCs < 1 μg/L). Therefore, this study suggests that the H2O2-Fe(II) process is an efficient and green technology for the removal of M. aeruginosa and PS composite pollutants without secondary pollution, which is promising technology in drinking water treatment plant.

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通过氧化强化混凝法同时去除铜绿微囊藻和微塑料
复合污染是水处理领域日益严峻的挑战。特别是微塑料(MPs)污染和铜绿微囊藻(M. aeruginosa)被证实可协同对饮用水安全构成严重威胁。因此,开发有效的去除技术迫在眉睫。本研究采用 H2O2 增强铁(II)混凝技术研究了同时去除铜绿微囊藻和聚苯乙烯(PS,一种典型的塑料物质)的方法。结果表明,藻类和聚苯乙烯的去除率都能达到 90% 以上。结果还表明,随着铜绿微囊藻生物量从 0 个细胞/毫升增加到 0.5×106 个细胞/毫升,PS 的去除率从 23.3% 提高到 97.3%。可能的原因是藻细胞的加入增加了污染物颗粒的数量,从而大大增加了混凝过程中的絮体尺寸。这使得 MPs 在此过程中更容易被扫絮凝截留。此外,自然风化聚苯乙烯(NWPS)比原始聚苯乙烯具有更高的去除率,这是由于原始聚苯乙烯具有更多的官能团、更大的粒径(d50 从 9.75 μm 到 11.25 μm)和更低的绝对 zeta 电位(从 -34.15 mV 到 -30.1 mV)。此外,该工艺还同时实现了低铁残留水平和 AOM(藻类有机物)控制(TOC < 1 mg/L,MCs < 1 μg/L)。因此,这项研究表明,H2O2-Fe(II)工艺是一种高效、绿色的去除铜绿微囊藻和 PS 复合污染物的技术,不会造成二次污染,在饮用水处理厂中是一种很有前景的技术。
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来源期刊
Environmental Pollution
Environmental Pollution 环境科学-环境科学
CiteScore
16.00
自引率
6.70%
发文量
2082
审稿时长
2.9 months
期刊介绍: Environmental Pollution is an international peer-reviewed journal that publishes high-quality research papers and review articles covering all aspects of environmental pollution and its impacts on ecosystems and human health. Subject areas include, but are not limited to: • Sources and occurrences of pollutants that are clearly defined and measured in environmental compartments, food and food-related items, and human bodies; • Interlinks between contaminant exposure and biological, ecological, and human health effects, including those of climate change; • Contaminants of emerging concerns (including but not limited to antibiotic resistant microorganisms or genes, microplastics/nanoplastics, electronic wastes, light, and noise) and/or their biological, ecological, or human health effects; • Laboratory and field studies on the remediation/mitigation of environmental pollution via new techniques and with clear links to biological, ecological, or human health effects; • Modeling of pollution processes, patterns, or trends that is of clear environmental and/or human health interest; • New techniques that measure and examine environmental occurrences, transport, behavior, and effects of pollutants within the environment or the laboratory, provided that they can be clearly used to address problems within regional or global environmental compartments.
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