Lixia Sun, Yunlong Zhang, Bo Wu, Enzhu Hu, Linlin Li, Longlong Qu and Shuqi Li
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The results showed that: (1) For fractionations ≤0.15 mm and from 0.15–2 mm, the materials demonstrating the highest average unit stabilisation efficiency were phosphate (45.0%/%) and organic matter (59.5%/%), respectively. (2) The smaller the size of soil particles, the greater the effect of the initial pH on stabilisation efficiency. (3) Similarly, for soil organic matter, smaller particle sizes (≤0.15 mm) combined with a lower initial content (≤1%) significantly increased the heavy metal stabilisation efficiency. (4) The impact of soil particle size fractionation on unit stabilisation efficiency was observed to be similar for typical heavy metals, specifically Cd and Pb. The relationship between particle size and unit stabilisation efficiency shows an inverted U shape. 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引用次数: 0
摘要
由于重金属在不同粒径土壤中的分布存在明显差异,因此按粒径分离受重金属污染的土壤对于最大限度地减少受污染土壤的体积至关重要。然而,关于土壤粒径分选对稳定化效果的相关分析却很有限。因此,我们筛选了 Web of Science 数据库中 2010 年 1 月至 2022 年 4 月间发表的 2766 篇同行评审论文,其中 117 篇符合筛选要求,并进行了荟萃分析,以探讨土壤粒径分选以及分选粒径与土壤性质之间的相互作用如何影响重金属的稳定化。结果表明(1)分选粒径≤0.15 毫米和 0.15-2 毫米时,平均单位稳定效率最高的材料分别是磷酸盐(45.0%/%)和有机质(59.5%/%)。(2)土壤颗粒越小,初始 pH 值对稳定效率的影响越大。(3) 同样,对于土壤有机质,粒径越小(≤0.15 毫米),初始含量越低(≤1%),重金属稳定效率就越高。(4) 对于典型的重金属,特别是镉和铅,观察到土壤粒度分馏对单位稳定效率的影响相似。粒度与单位稳定效率之间的关系呈倒 U 型。粒度分选会影响重金属的分布,但还应结合土壤特性和重金属类型来考虑稳定剂的类型。
Impact of particle size separation on the stabilisation efficiency of heavy-metal-contaminated soil: a meta-analysis†
The separation of heavy-metal-contaminated soil by particle size is crucial for minimising the volume of contaminated soil because of the pronounced variability in the heavy-metal distribution among different soil particle sizes. However, relevant analyses on the effect of soil particle size sorting on stabilisation are limited. Therefore, we screened 2766 peer-reviewed papers published from January 2010 to April 2022 in the Web of Science database, of which 117 met the screening requirements, and conducted a meta-analysis to explore how soil particle size sorting and the interaction between sorting particle size and soil properties affect the stabilisation of heavy metals. The results showed that: (1) For fractionations ≤0.15 mm and from 0.15–2 mm, the materials demonstrating the highest average unit stabilisation efficiency were phosphate (45.0%/%) and organic matter (59.5%/%), respectively. (2) The smaller the size of soil particles, the greater the effect of the initial pH on stabilisation efficiency. (3) Similarly, for soil organic matter, smaller particle sizes (≤0.15 mm) combined with a lower initial content (≤1%) significantly increased the heavy metal stabilisation efficiency. (4) The impact of soil particle size fractionation on unit stabilisation efficiency was observed to be similar for typical heavy metals, specifically Cd and Pb. The relationship between particle size and unit stabilisation efficiency shows an inverted U shape. Particle size sorting can affect the distribution of heavy metals, but the type of stabilisation agent should also be considered in combination with the soil properties and heavy metal types.
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.