Deciphering the Roles of Molecular Weight and Carboxyl Richness of Organic Matter on Their Adsorption onto Ferrihydrite Nanoparticles and the Resulting Aggregation

IF 10.8 1区环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL

环境科学与技术 Pub Date : 2024-11-08 DOI:10.1021/acs.est.4c06885

Zhixiong Li, Stacey M. Louie, Juntao Zhao, Juanjuan Liu, Jing Zhang, Jiawei Chen, Huazhang Zhao, Yandi Hu

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Abstract

The aggregation behavior of ferrihydrite nanoparticles (FNPs) can control the fate of associated aqueous contaminants, trace elements, and organic compounds. However, FNP aggregation is difficult to predict in the presence of organic matter (OM), given the heterogeneity in the OM properties. Five model OMs based on (poly)acrylic acid (PAA or AA) and polyethylene glycol with or without terminal carboxyl groups (PEG or PEGbis, respectively) were chosen to probe the influence of key OM properties─specifically, carboxyl richness and molecular weight (MW)─and the dominant mechanisms by which they influence OM adsorption onto FNPs and the resulting aggregation. For OMs with similar MWs, those with a higher carboxyl richness adsorbed more extensively onto FNPs: PAA_2k > PEGbis > PEG. Meanwhile, for OMs with the same carboxyl richness, higher MW OMs adsorbed more: PAA_25k > PAA_2k > AA. Furthermore, the subsequent aggregation of FNPs was largely controlled by the adsorbed mass. OMs with negligible adsorption (i.e., PEG and AA) did not change the aggregation behavior of FNPs. For OMs with low carboxyl richness (PEGbis), accelerated aggregation occurred through a bridging effect with low adsorbed mass. For OMs with high carboxyl richness (PAA_2k and PAA_25k), aggregation was accelerated at moderate adsorbed OM masses by patch-charge attraction and was inhibited with high adsorbed OM mass due to steric repulsion. This study provided new insights into understanding and predicting the transport and fate of FNPs and natural organic matter (NOM) in natural environments with various NOM compositions.

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解读有机物质的分子量和羧基富集度对其吸附到铁酸盐纳米粒子上并导致团聚的作用

铁水纳米粒子（FNPs）的聚集行为可以控制相关水污染物、微量元素和有机化合物的归宿。然而，由于有机物（OM）特性的异质性，在有机物（OM）存在的情况下，FNP 的聚集很难预测。我们选择了五种基于（聚）丙烯酸（PAA 或 AA）和聚乙二醇（分别带有或不带有末端羧基（PEG 或 PEGbis））的模型 OM，以探究关键 OM 特性（特别是富含羧基和分子量（MW））的影响，以及它们影响 OM 吸附到 FNPs 上并导致其聚集的主要机制。在分子量相似的 OMs 中，羧基丰富度越高的 OMs 在 FNPs 上的吸附越广泛：PAA2k > PEGbis > PEG。同时，对于富含相同羧基的 OM，分子量较高的 OM 吸附得更多：PAA25k > PAA2k > AA。此外，FNPs 随后的聚集在很大程度上受吸附质量的控制。吸附量可忽略不计的 OMs（即 PEG 和 AA）不会改变 FNPs 的聚集行为。对于羧基富集度较低的 OMs（PEGbis），通过低吸附质量的桥接效应加速了聚集。对于羧基富集度较高的 OM（PAA2k 和 PAA25k），当吸附的 OM 质量适中时，通过贴片电荷吸引作用会加速聚集，而当吸附的 OM 质量较高时，由于立体排斥作用会抑制聚集。这项研究为理解和预测 FNPs 和天然有机物（NOM）在不同 NOM 组成的自然环境中的迁移和归宿提供了新的见解。

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来源期刊

环境科学与技术环境科学-工程：环境

CiteScore

17.50

自引率

9.60%

发文量

12359

审稿时长

2.8 months

期刊介绍： Environmental Science & Technology (ES&T) is a co-sponsored academic and technical magazine by the Hubei Provincial Environmental Protection Bureau and the Hubei Provincial Academy of Environmental Sciences. Environmental Science & Technology (ES&T) holds the status of Chinese core journals, scientific papers source journals of China, Chinese Science Citation Database source journals, and Chinese Academic Journal Comprehensive Evaluation Database source journals. This publication focuses on the academic field of environmental protection, featuring articles related to environmental protection and technical advancements.