Mobility of biochar-derived dissolved organic matter and its effects on sulfamerazine transport through saturated soil porous media†

IF 4.3 3区 环境科学与生态学 Q1 CHEMISTRY, ANALYTICAL
Mengya Liu, Xiaochen Liu, Yalu Hu, Qiang Zhang, Usman Farooq, Zhichong Qi and Laotao Lu
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Abstract

Dissolved organic matter (DOM) released from biochar may impact antibiotic mobility and environmental fate in subsurface environments. Here, DOM samples derived from biochars (BDOM) generated by pyrolyzing corn straw at 300, 450, and 600 °C were employed to elucidate the mobility characteristics of these organic substances and their influences on the transport of sulfamerazine (SMZ, a typical sulfonamide antibiotic) in soil porous media. The results demonstrated that BDOM produced at a lower pyrolysis temperature exhibited greater mobility owing to the weaker hydrophobic and H-bonding interactions between BDOM and soil particles. Additionally and importantly, BDOM facilitated the promotion of SMZ mobility owing to the increased electrostatic repulsion between SMZ forms and soil grains, the steric hindrance effect induced by the deposition of organic matter, and the competitive retention between SMZ molecules and BDOM. Meanwhile, the promotion effects of BDOM enhanced with improving pyrolysis temperature owing to the promoted deposition of organic matter on soil surfaces and the strengthened electrostatic repulsion. Moreover, the facilitated effects of BDOM on SMZ mobility declined as the solution pH values were raised from 5.0 to 9.0 or the flow rate increased from 0.18 to 0.51 cm min−1. This trend was due to decreased deposition competition and the steric effect caused by decreased retention of BDOM on soil particles. Furthermore, the cation-bridging effect emerged as an important mechanism contributing to the promotion effects of BDOM when the solution contained divalent cations (Cu2+ or Ca2+). Moreover, a two-site non-equilibrium model was used to interpret the controlling mechanisms for the effects of BDOM on the transport of SMZ. Findings from this work highlight that biochar-derived dissolved organic matter can remarkably affect the environmental behaviors of antibiotics in aquatic environments.

Abstract Image

生物炭溶解有机物的流动性及其对磺胺甲基嘧啶在饱和土壤多孔介质中迁移的影响。
生物炭释放的溶解有机物(DOM)可能会影响抗生素在地下环境中的迁移性和环境归宿。在此,研究人员利用在 300、450 和 600 °C 下热解玉米秸秆产生的生物炭(BDOM)中的 DOM 样品,来阐明这些有机物质的迁移特性及其对磺胺类抗生素磺胺甲基嘧啶(SMZ,一种典型的磺胺类抗生素)在土壤多孔介质中迁移的影响。结果表明,由于 BDOM 与土壤颗粒之间的疏水作用和 H 键作用较弱,在较低的热解温度下产生的 BDOM 表现出更大的流动性。此外,重要的是,由于 SMZ-形式与土壤颗粒之间的静电斥力增加、有机物沉积引起的立体阻碍效应以及 SMZ 分子与 BDOM 之间的竞争性滞留,BDOM 促进了 SMZ 的流动性。同时,随着热解温度的提高,BDOM 的促进作用也会增强,这是由于有机物在土壤表面的沉积作用和静电排斥作用增强所致。此外,当溶液 pH 值从 5.0 升至 9.0 或流速从 0.18 厘米/分钟升至 0.51 厘米/分钟时,BDOM 对 SMZ 移动性的促进作用下降。这一趋势是由于沉积竞争的减少以及 BDOM 在土壤颗粒上的滞留减少所导致的立体效应。此外,当溶液中含有二价阳离子(Cu2+ 或 Ca2+)时,阳离子桥接效应成为 BDOM 起促进作用的重要机制。此外,还使用了一个双位点非平衡模型来解释 BDOM 对 SMZ 运输影响的控制机制。这项研究的结果表明,生物炭衍生的溶解有机物可显著影响抗生素在水生环境中的环境行为。
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来源期刊
Environmental Science: Processes & Impacts
Environmental Science: Processes & Impacts CHEMISTRY, ANALYTICAL-ENVIRONMENTAL SCIENCES
CiteScore
9.50
自引率
3.60%
发文量
202
审稿时长
1 months
期刊介绍: Environmental Science: Processes & Impacts publishes high quality papers in all areas of the environmental chemical sciences, including chemistry of the air, water, soil and sediment. We welcome studies on the environmental fate and effects of anthropogenic and naturally occurring contaminants, both chemical and microbiological, as well as related natural element cycling processes.
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