Real-time two-dimensional visualization reveals the transport mechanisms of biochar colloids in the presence of DOM in porous media

[Display omitted] •LTV visualized the real-time transport of BCs in the presence of DOM.•Soil DOM facilitates the transport of BCs.•The transport mechanisms of BCs in the presence of DOM are revealed.•Double-Monod model can match BCs transport and retention behavior. Biochar colloids (BCs) have attr...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2024-11, Vol.643, p.132017, Article 132017
Main Authors: Zhao, Ying, Song, Jian, Lyu, Xueyan, Cao, Shaohua, Liu, Zhuqing, Yang, Fan
Format: Article
Language:English
Subjects:
biochar
Biochar colloids
Dissolved organic matter
hydrology
organic matter
particle size
Porous media
soil
Two-dimensional
Visualization
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Summary:[Display omitted] •LTV visualized the real-time transport of BCs in the presence of DOM.•Soil DOM facilitates the transport of BCs.•The transport mechanisms of BCs in the presence of DOM are revealed.•Double-Monod model can match BCs transport and retention behavior. Biochar colloids (BCs) have attracted much attention globally, and their fate and transport in the subsurface are significantly influenced by soil-dissolved organic matter (DOM) in soil. This study utilized a real-time and non-invasive visualization system to reveal the transport and retention behavior of BCs in the presence of DOM in two-dimensional porous media. Results indicated that the presence of DOM enhanced the transport of BCs, due to its increased negative charge density and increased repulsion between BCs. The change in the particle size of the porous medium was also shown to affect the BCs transport in the porous media. Additionally, the negative charge of BCs shielded by high IS, the mobility of BCs decreased by 30.37 % from 1 mM to 50 mM. When the pH was increased from 5 to 9, the oxygen-containing functional groups of BCs and DOM were dissociated, and the mobility of BCs increased by 32.41 %. Through a simplified Double-Monod model, we fitted the breakthrough curves for BCs transport in porous media (R2 > 0.94). Moreover, the mechanism of different conditions on colloid clogging behavior was further elucidated through the DLVO theory. These findings extend the understanding of the environmental behavior of BCs in the presence of DOM derived from soil, enabling us to assess better and predict their environmental risks.
ISSN:0022-1694
DOI:10.1016/j.jhydrol.2024.132017