Time-dependent redistribution of soil arsenic induced by transformation of iron species during zero-valent iron biochar composites amendment: Effects on the bioaccessibility of As in soils.

IF 8.2 1区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Science of the Total Environment Pub Date : 2024-12-10 Epub Date: 2024-10-17 DOI:10.1016/j.scitotenv.2024.176956

Liyang Hu, Xiaoyun Xu, Xiangyang Gui, Jun Liang, Ling Zhao, Hao Qiu, Xinde Cao

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Abstract

Zero-valent iron biochar composites (ZVI/BC) are considered as effective amendments for arsenic (As)-contaminated soils. However, the mechanisms of transformation of various soil As species during ZVI/BC amendments remain unclear. This study investigated As transformation in four soils (namely, GX, ZJ, HB, and HN) treated with ZVI/BC for 65 days under two soil moisture conditions, unsaturated and oversaturated. Results showed that the 65-day treatment was divided into two stages based on the variation of labile As content. Within 2 days (stage 1), ZVI/BC addition quickly reduced labile As content by 5.91-90.3 % in soils under unsaturated conditions. During days 2-65 (stage 2), labile As ultimately decreased by 0.06-0.31 mg/kg in GX, ZJ, and HB while increasing by 22.1 mg/kg in HN soil, due to its lower pH value and Fe content. The variations of labile As were attributed to changes in multiple Fe minerals and associated As species. In stage 1, the corrosion of ZVI/BC generated amorphous Fe oxides to immobilize labile As, resulting in the accumulation of meta-stable As. In stage 2, amorphous Fe oxides were transformed into crystalline Fe oxides, resulting in the release and re-precipitation of As along with transformation, thus redistributing immobilized As into labile and stable As, which was evidenced by multiple methods, including chemical extraction, XRD, and TEM-EDX. The elevated soil moisture condition would enhance the corrosion of ZVI/BC in stage 1, further forming a reductive environment to facilitate the transformation of Fe minerals in stage 2. Besides, As bioaccessibility in soils was reduced by 10.8-38.7 % after ZVI/BC treatment in in-vitro gastrointestinal simulations. Overall, our study revealed the time-dependent transformation mechanism of soil As species and associated Fe minerals under different soil moisture with ZVI/BC treatments, and highlighted the effectiveness of ZVI/BC as a long-term amendment for As-contaminated soils.

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在零价铁生物炭复合材料改良过程中，由铁物种转化引起的土壤砷的重新分布随时间变化：对土壤中砷的生物可及性的影响。

零价铁生物炭复合材料（ZVI/BC）被视为砷（As）污染土壤的有效改良剂。然而，ZVI/BC 在改良过程中各种土壤砷物种的转化机制仍不清楚。本研究调查了在非饱和和过饱和两种土壤湿度条件下，用 ZVI/BC 处理 65 天的四种土壤（即 GX、ZJ、HB 和 HN）中砷的转化情况。结果表明，根据易溶砷含量的变化，65 天的处理分为两个阶段。在非饱和条件下，添加 ZVI/BC 2 天内（第 1 阶段），土壤中的可迁移砷含量迅速降低了 5.91-90.3%。在第 2-65 天（第 2 阶段）中，由于 GX、ZJ 和 HB 土壤中的 pH 值和铁含量较低，其游离砷含量最终降低了 0.06-0.31 mg/kg，而 HN 土壤中的游离砷含量则增加了 22.1 mg/kg。易溶砷的变化归因于多种铁矿物和相关砷物种的变化。在第 1 阶段，ZVI/BC 的腐蚀产生了非晶态铁氧化物，固定了可迁移砷，导致元稳定砷的积累。在第 2 阶段，无定形铁氧化物转化为结晶铁氧化物，在转化的同时导致砷的释放和再沉淀，从而将固定砷重新分配为易变砷和稳定砷，化学萃取、XRD 和 TEM-EDX 等多种方法都证明了这一点。土壤湿度的升高会在第一阶段增强 ZVI/BC 的腐蚀，并在第二阶段进一步形成还原环境，促进铁矿物的转化。此外，在体外胃肠道模拟中，经过 ZVI/BC 处理后，土壤中砷的生物可及性降低了 10.8%-38.7%。总之，我们的研究揭示了在不同土壤湿度下，ZVI/BC 处理后土壤中砷物种和相关铁矿物随时间变化的转化机制，并突出了 ZVI/BC 作为砷污染土壤长期改良剂的有效性。

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来源期刊

Science of the Total Environment 环境科学-环境科学

CiteScore

17.60

自引率

10.20%

发文量

8726

审稿时长

2.4 months

期刊介绍： The Science of the Total Environment is an international journal dedicated to scientific research on the environment and its interaction with humanity. It covers a wide range of disciplines and seeks to publish innovative, hypothesis-driven, and impactful research that explores the entire environment, including the atmosphere, lithosphere, hydrosphere, biosphere, and anthroposphere. The journal's updated Aims & Scope emphasizes the importance of interdisciplinary environmental research with broad impact. Priority is given to studies that advance fundamental understanding and explore the interconnectedness of multiple environmental spheres. Field studies are preferred, while laboratory experiments must demonstrate significant methodological advancements or mechanistic insights with direct relevance to the environment.