利用地球化学基线和 PMF 方法描述土壤中重金属的污染特征和来源识别。

Characterizing pollution and source identification of heavy metals in soils using geochemical baseline and PMF approach.

机构信息

Key Laboratory of Exploration Technologies for Oil and Gas Resources (Yangtze University), Ministry of Education, Wuhan, 430100, China.

College of Resources and Environment, Yangtze University, Wuhan, 430100, China.

出版信息

Sci Rep. 2020 Apr 15;10(1):6460. doi: 10.1038/s41598-020-63604-5.

DOI:10.1038/s41598-020-63604-5

PMID:32296085

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7160138/

Abstract

It is necessary to establish local geochemical baseline concentrations (GBCs) due to the lack or the inapplicability of regional background values in the study area. The establishment of GBCs of heavy metal (HM) in soil helps in making the accurate assessment of pollution, and then provides a basis for pollution control. Based on this, a case study was undertaken to study the GBCs of the Jiedong District, Guangdong Province, China. In this research, cumulative frequency distribution curves were utilized to determine the local GBCs in the subsoils. The determined GBCs of Cr, Hg, As, Pb, Ni, Cd, Cu, Zn, Co and V were 39.91, 0.072, 11.48, 47.62, 12.70, 0.17, 14.22, 64.54, 6.31, and 68.14 mg/kg, respectively. The average concentrations of Hg, As, Pb, Cd, Cu and Zn in the topsoils exceeded the corresponding baseline concentrations. In particular, the contents of Cd and Hg were 1.53 and 2.22 times higher than GBCs. According to this baseline criterion, enrichment factor (EF), pollution load index (PLI) and ecological risk index (RI) were applied to assessing HM pollution. EF and PLI suggested that most areas were under moderate contamination, while Hg and Cd pollution was more serious. And the RI values presented that the potential ecological risks were low in most parts of the study area. The possible origins of HMs were identified by combining positive matrix factorization with EF and geostatistics. Comprehensive analysis indicated that Hg and Cd were related to industrial activities, such as textile and garment processing, plastic and rubber production and metal manufacturing. Arsenic and part of Cu mainly came from agricultural activities, namely the use of pesticides, fertilizers and livestock manures. Lead and Zn were mainly attributed to traffic emissions. Chromium, Ni, V, Co, and part of Cu were originated from natural source controlled by parent materials. The corresponding contributions of these sources were 20.61%, 24.20%, 19.22% and 35.97%, respectively. This work provides information to prevent and control the soil HM pollution by proposing the efficient management of anthropogenic sources.

摘要

由于研究区域缺乏或不适用区域背景值，因此有必要建立当地地球化学背景浓度（GBC）。建立土壤重金属（HM）的 GBC 有助于准确评估污染程度，为污染控制提供依据。基于此，本研究以广东省揭东区为例，开展了 GBC 研究。本文利用累积频率分布曲线确定了土壤亚层的 GBC。研究确定的 Cr、Hg、As、Pb、Ni、Cd、Cu、Zn、Co 和 V 的 GBC 分别为 39.91、0.072、11.48、47.62、12.70、0.17、14.22、64.54、6.31 和 68.14mg/kg。表层土壤中 Hg、As、Pb、Cd、Cu 和 Zn 的平均浓度超过了相应的背景浓度。特别是 Cd 和 Hg 的含量分别是 GBC 的 1.53 和 2.22 倍。根据这一基线标准，采用富集因子（EF）、污染负荷指数（PLI）和生态风险指数（RI）对重金属污染进行评价。EF 和 PLI 表明，大部分地区处于中度污染水平，而 Hg 和 Cd 污染较为严重。RI 值表明研究区大部分地区的潜在生态风险较低。通过结合正矩阵因子分解、EF 和地统计学，确定了重金属的可能来源。综合分析表明，Hg 和 Cd 与纺织服装加工、塑料橡胶生产和金属制造等工业活动有关。砷和部分 Cu 主要来自农业活动，即农药、化肥和牲畜粪便的使用。铅和锌主要归因于交通排放。Cr、Ni、V、Co 和部分 Cu 主要来自受母质控制的自然源。这些来源的相应贡献分别为 20.61%、24.20%、19.22%和 35.97%。本研究通过提出人为源的有效管理措施，为预防和控制土壤重金属污染提供了信息。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e136/7160138/452429ab4a89/41598_2020_63604_Fig1_HTML.jpg

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利用地球化学基线和 PMF 方法描述土壤中重金属的污染特征和来源识别。

Characterizing pollution and source identification of heavy metals in soils using geochemical baseline and PMF approach.

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