Transport and retention of microplastics in saturated porous media with peanut shell biochar (PSB) and MgO-PSB amendment: Co-effects of cations and humic acid

Biochar particles are extensively used in soil remediation and interact with microplastics (MPs), especially metal oxide-modified biochar may have stronger interactions with MPs. The mechanism of interactions between humic acid (HA) and different valence cations is different and the co-effect on the...

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Bibliographic Details
Published in:Environmental pollution (1987) 2022-07, Vol.305, p.119307-119307, Article 119307
Main Authors: Wang, Xiaoxia, Dan, Yitong, Diao, Yinzhu, Liu, Feihong, Wang, Huan, Sang, Wenjing
Format: Article
Language:English
Subjects:
Biochar
Cations
Humic acid
Microplastics
Transport and retention
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Summary:Biochar particles are extensively used in soil remediation and interact with microplastics (MPs), especially metal oxide-modified biochar may have stronger interactions with MPs. The mechanism of interactions between humic acid (HA) and different valence cations is different and the co-effect on the transport of MPs is not clear. In this study, the co-effects of HA and cations (Na+, Ca2+) on the transport and retention of MPs in saturated porous media with peanut shell biochar (PSB) and MgO-modified PSB (MgO-PSB) were systematically investigated. Breakthrough curves (BTCs) of MPs were fitted by the two-site kinetic retention model for analysis. In the absence of HA, the addition of PSB and MgO-PSB significantly hindered the transport of MPs in saturated porous media, and the retention of MPs increased from 34.2% to 59.1% and 75.5%, respectively. In Na+ solutions, the HA concentration played a dominant role in controlling MPs transport, compared to the minor role of Na+. The transport capacity of MPs always increased gradually with the increase of HA concentration. Whereas, in Ca2+ solutions, Ca2+ concentrations had a stronger effect than HA. The transport ability of MPs was instead greater than that in Na+ solutions as the HA concentration increased at low ionic strength (1 mM). However, the transport capacity of MPs was significantly reduced with increasing HA concentrations at higher ionic strength (10, 100 mM). The two-site kinetic retention model indicated that chemical attachment and physical straining are the main mechanisms of MPs retention in the saturated porous media. [Display omitted] •MgO modified biochar had a significant removal (>75.53%) for microplastics (MPs).•Humic acid (HA) in higher Ca2+ solutions (>10 mM) reduced transport of MPs by clogging.•HA decreased the retention of MPs even with the presence of biochar in Na+ solutions.•Breakthrough curves of MPs were well fitted by the two-site kinetic retention model.
ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2022.119307