载纳米零价铁凹凸棒土去除地下水中硝酸盐氮的研究

Yangyang Zhang, Yunfeng Tan, B. Zu, Xiaotian Zhang, Chunli Zheng, Zishen Lin, F. He, Ke Chen
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引用次数: 1

摘要

纳米零价铁(nZVI)可用于去除地下水中的硝态氮(NO3-N)。但由于其氧化和聚集特性,其还原效率较低。因此,nzvi加载材料被用来减轻这些缺点。本研究制备了nzvi包覆凹凸棒土(ATP),用于去除地下水中的NO3-N。采用化学液相沉积-共还原法制备ATP-nZVI。对制备的材料进行了SEM、XRD和XPS表征,证实了ATP结构的硅酸铝颗粒是nZVI的有效载体,有效抑制了nZVI氧化聚集引起的自耗。通过批量实验检测含有30 mg/L硝酸盐的实验样品,分析了材料、质量比、初始pH、初始温度、共存阴离子等参数对NO3-N去除率的影响。结果表明,复合材料的最佳去除率为78.61%,高于相同用量的ATP、铁粉和nZVI的去除率。当ATP与nZVI的质量比为1:1时,NO3-N的去除率最高。当pH值从3增加到9时,NO3-N的去除率降低,而反应温度的升高促进了NO3-N的去除率。共存阴离子对不同纳米离子去除NO3-N的抑制作用顺序为PO43 - >CO32 - >SO42 - >Cl -。吸附动力学模型拟合结果表明,ATP与nZVI之间的电子交换的化学吸附是该反应的主要限速步骤。本研究证明了所制备的ATP-nZVI复合材料去除地下水中NO3-N的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Removal of Nitrate Nitrogen in Groundwater by Attapulgite Loaded with Nano-Zero-Valent Iron
Nano-zero-valent iron (nZVI) can be used to remove nitrate nitrogen (NO3-N) from groundwater. However, it has low reduction efficiency owing to its oxidation and aggregation characteristics. Thus, nZVI-loaded material is used to alleviate these drawbacks. In this study, nZVI-coated attapulgite (ATP) was prepared for the removal of NO3-N from groundwater. ATP-nZVI was prepared using the chemical liquid deposition-coreduction method. The prepared materials were characterized by SEM, XRD, and XPS analyses, which confirmed that the aluminum silicate particles in the ATP structure are effective carriers of nZVI and effectively inhibit self-consumption caused by the oxidation and aggregation of nZVI. The batch experiments examined experimental samples containing 30 mg/L nitrate and analyzed the effects of various parameters, including the material, mass ratio, initial pH, initial temperature, and coexisting anions on the NO3-N removal efficiency. The results showed that the optimal removal rate of the composite was 78.61%, which is higher than that using the same amount of ATP, iron powder, and nZVI. When the mass ratio of ATP to nZVI was 1 : 1, the NO3-N removal efficiency was the highest. When the pH value increased from 3 to 9, the NO3-N removal rate decreased, while an increase in the reaction temperature promoted NO3-N removal. The order of the inhibitory effect of coexisting anions on NO3-N removal by various nanoions was PO43–>CO32–>SO42–>Cl–. The adsorption kinetic model fitting results indicated that the chemisorption of electron exchange between ATP and nZVI in NO3-N removal was the main rate-limiting step in the reaction. This study demonstrates the potential of the prepared ATP-nZVI composite for NO3-N removal from groundwater.
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