Stabilization and Remediation of Arsenic-Contaminated Soil: Fly Ash-Based Technology for Industrial Site Restoration

IF 3.3 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Sustainability Pub Date : 2024-09-18 DOI:10.3390/su16188132

Jiang Yu, Jianguo Bao, Qu Su, Wuzhu Zhang, Bei Ye, Xingzhu Zhou, Hongcheng Li, Xing Li

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Abstract

Arsenic contamination of various environmental components poses a serious threat to human and animal health. Soil As contamination is particularly hazardous, as soil is a vital pathway to the food chain. We conducted experiments on soil from a typical pharmaceutical and chemical industry relocation site in Hubei Province, focusing on modification using fly ash through mechanical and chemical mechanisms. We subjected varying proportions of lime, ferrous sulfate, and fly ash to mechanical ball milling and used these mixtures to perform remediation of arsenic-contaminated soil and site restoration. Our findings are as follows: in soil culture experiments, the As stabilization efficiency reached 90% within 90 days with ferrous salt-modified fly ash. In actual site restoration, As-stabilization efficiency exceeded 95% across different soil depths within 30 days, demonstrating significant stabilization effects. Optimal modified dosages were determined as 2% ferrous sulfate and 2% fly ash. After stabilization, As in the soil primarily existed in amorphous iron-aluminum oxide-bound (F3) and crystalline iron-aluminum oxide-bound (F3 + F4) and residual (F5) states. Fluctuations in the moisture content and pH mainly activated F3 and F4, transitioning them into exchangeable (F1) and surface-adsorbed (F2) states. Arsenic leaching was predominantly associated with the F1 form. Fly ash-based restoration technology demonstrates promising capabilities in waste treatment and pollution control, offering significant potential for widespread application.

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砷污染土壤的稳定与修复：基于粉煤灰的工业场地修复技术

各种环境成分中的砷污染严重威胁着人类和动物的健康。土壤砷污染尤其危险，因为土壤是食物链的重要途径。我们对湖北省一个典型的制药和化工行业搬迁地的土壤进行了实验，重点是利用粉煤灰通过机械和化学机制进行改良。我们将不同比例的石灰、硫酸亚铁和粉煤灰进行机械球磨，并使用这些混合物对砷污染土壤进行修复和场地恢复。我们的研究结果如下：在土壤培养实验中，使用盐改性粉煤灰的砷稳定效率在 90 天内达到 90%。在实际场地修复中，不同土壤深度的砷稳定效率在 30 天内超过 95%，显示出显著的稳定效果。最佳改性剂量被确定为 2% 的硫酸亚铁和 2% 的粉煤灰。稳定化后，土壤中的 As 主要以无定形氧化铁铝结合态（F3）、结晶氧化铁铝结合态（F3 + F4）和残留态（F5）存在。含水量和 pH 值的波动主要激活了 F3 和 F4，使其转变为可交换状态（F1）和表面吸附状态（F2）。砷沥滤主要与 F1 形态有关。以粉煤灰为基础的修复技术在废物处理和污染控制方面表现出良好的能力，具有广泛应用的巨大潜力。

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来源期刊

Sustainability ENVIRONMENTAL SCIENCES-ENVIRONMENTAL SCIENCES

CiteScore

6.80

自引率

20.50%

发文量

14120

审稿时长

17.72 days

期刊介绍： Sustainability (ISSN 2071-1050) is an international and cross-disciplinary scholarly, open access journal of environmental, cultural, economic and social sustainability of human beings, which provides an advanced forum for studies related to sustainability and sustainable development. It publishes reviews, regular research papers, communications and short notes, and there is no restriction on the length of the papers. Our aim is to encourage scientists to publish their experimental and theoretical research relating to natural sciences, social sciences and humanities in as much detail as possible in order to promote scientific predictions and impact assessments of global change and development. Full experimental and methodical details must be provided so that the results can be reproduced.