Transport of reduced PBAT microplastics in saturated porous media: Synergistic effects of enhanced surface energy and roughness

•Reduction aging improved the mobility of PBAT in porous media.•Increased roughness and surface energy were key effects for reduced PBAT mobility.•Increased IS and the presence of LMWOAs inhibited the transport of reduced PBAT.•Reduced PBAT with low oxygen functional group content blocked cationic b...

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Published in:Water research (Oxford) 2024-12, Vol.267, p.122514, Article 122514
Main Authors: Wang, Binying, Wu, Lan, Pang, Kejing, Zhang, Guangcai, Xu, Duo, Sun, Huimin, Yin, Xianqiang
Format: Article
Language:English
Subjects:
Microplastics
Polyesters - chemistry
Porosity
Reduction aging
Roughness
Surface energy
Surface Properties
Transport
Water Pollutants, Chemical - chemistry
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Summary:•Reduction aging improved the mobility of PBAT in porous media.•Increased roughness and surface energy were key effects for reduced PBAT mobility.•Increased IS and the presence of LMWOAs inhibited the transport of reduced PBAT.•Reduced PBAT with low oxygen functional group content blocked cationic bridging.•Carboxylate group of LMWOAs played a key role in the retention of reduced PBAT. Microplastic (MP) pollution presents significant global environmental challenges, exacerbated by reduction aging processes in anoxic environments, thereby increasing environmental risks and potential threats to human health. However, the mechanisms underlying the transport of reduced MPs remain poorly understood. In this study, laboratory-scale column experiments were conducted to investigate the transport behavior of polybutylene adipate terephthalate (PBAT), a common biodegradable MPs, and its reduced products obtained through the aging process mediated by two typical reducing agents, NaBH4 and Na2S, under varying conditions (ionic strength (IS), divalent cations, and low molecular weight organic acids (LMWOAs)). The results indicated that reduction aging improved the hydrophilicity of PBAT by increasing the surface roughness (roughness factor increased from 1.300 to 1.642) and surface energy (from 51.80 to 107.03 mN m−1), thereby increasing the mobility of reduced PBAT (with recovery rate increased from 53.77 % to 63.18 %). Increased IS decreased the mobility of reduced PBAT by decreasing the surface negative charge density. Divalent cations inhibited the mobility of both pristine and reduced PBAT in porous media, with pristine PBAT, containing more oxygen functional groups, exhibiting stronger inhibition. Furthermore, LMWOAs promoted the retention of reduced PBAT in porous media, which was dependent on the type of LMWOAs. This study revealed the alterations in MPs properties caused by reduction aging and their effects on transport mechanisms, offering new insights into the transport behavior and environmental risks of reduced MPs. [Display omitted]
ISSN:0043-1354
1879-2448
1879-2448
DOI:10.1016/j.watres.2024.122514