农业土壤、蔬菜和水果中潜在有毒元素(PTEs)与铅酸蓄电池工业附近距离梯度的生态风险评估

Q1 Environmental Science
Fatema Akter Lima , Shovon Bhattacharjee , Md. Jahangir Sarker , Mohammed Abdus Salam
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引用次数: 0

摘要

孟加拉国的铅酸电池工业在城市地区激增,导致大量潜在有毒元素 (PTE) 和类金属释放到环境中。本研究旨在评估这些工业附近农业土壤、蔬菜和水果的空间分布、来源、污染状况和生态风险。2020 年 6 月至 7 月期间,在达卡和加济布尔地区的三家铅酸蓄电池企业(AA、AB 和 AC)周围不同距离(0 米、100 米、250 米和 500 米)的四个地点采集了土壤样本。农业土壤中铅、砷、镉和锌的浓度范围分别为 8.40-116.61、8.99-28.21、0.03-1.28 和 25.38-68.72毫克/千克。污染因子表明,农业土壤受到砷、镉和铅的高度至中度污染,而受到锌的低度污染。污染负荷指数、修正污染度和 nemerow 综合指数表明,工业附近的污染程度不同,AA 和 AB 的污染程度高于 AC。单个风险因素显示,镉和砷暴露的风险很大,而铅和锌的风险较低。潜在生态风险指数显示,AA(风险指数 = 192.41)具有相当大的生态风险,AB(风险指数 = 111.80)和 AC(风险指数 = 65.08)具有中等风险。相关性和主成分分析表明,土壤中的化学参数和潜在有毒元素之间存在很强的正相关性(p < 0.01),并表明铅酸蓄电池行业是研究地区的主要污染源。土壤中的砷、镉和锌与蔬菜中的砷、镉和锌之间存在很强的正相关关系(p < 0.01),而土壤中的砷与水果中的砷之间存在很强的负相关关系。聚类分析显示,EC、OC、OM、Pb、As 和 Zn 被分为不同的组,这意味着它们的来源都是人为的。蔬菜和水果样品对金属的吸收率依次为镉、锌、砷、铅和镉、锌、铅、砷,转移因子分析显示镉和锌是蔬菜和水果中吸收率较高的金属。在各行业中,AA 和 AB 对土壤质量的影响较大,在蔬菜中发现了大量的金属积累。人类健康风险评估结果表明,对工业(AA、AB 和 AC)周围的人群而言,存在潜在的非致癌健康危害。总目标危害商数和危害指数的计算结果都超过了可接受水平(1)。不过,食用潜在有毒元素所产生的致癌健康风险还在阈值范围之内。这项研究为了解铅酸蓄电池行业对环境和健康的影响提供了重要依据,并强调了实施有效的环境管理措施以减轻其后果的紧迫性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Ecological risk assessment of potentially toxic elements (PTEs) in agricultural soil, vegetables and fruits with respect to distance gradient in proximity to lead-acid battery industry

Ecological risk assessment of potentially toxic elements (PTEs) in agricultural soil, vegetables and fruits with respect to distance gradient in proximity to lead-acid battery industry

Lead-acid battery industries in Bangladesh have proliferated in urban areas, leading to the release of significant amounts of potentially toxic elements (PTEs) and metalloids into the environment. This study aimed to assess the spatial distribution, sources, contamination status, and ecological risks in agricultural soils, vegetables, and fruits near these industries. Soil samples were collected from four sites at varying distances (0 m, 100 m, 250 m, and 500 m) around three lead-acid battery industries (AA, AB, and AC) in Dhaka and Gazipur Districts during June-July 2020. The concentrations of the Pb, As, Cd and Zn in agricultural soils were ranged between 8.40–116.61, 8.99–28.21, 0.03–1.28, and 25.38–68.72 mg/kg, respectively. The concentrations of Pb, As, and Cd were found to be considerably higher than background levels across all industries, with a gradual decrease in PTE concentrations from 0 m to 500 m. The contamination factor indicated high to moderate contamination in agricultural soils by As, Cd, and Pb, and low contamination by Zn. pollution load index, modified contamination degree, and nemerow comprehensive index revealed varying pollution levels in the vicinity of the industries, with AA and AB showing higher pollution compared to AC. The individual risk factors demonstrated significant risks associated with Cd and As exposure, while Pb and Zn posed lower risks. The potential ecological risk index indicated considerable ecological risk for AA (risk index = 192.41), moderate risk for AB (risk index = 111.80), AC (risk index = 65.08), respectively. Correlation and principal component analysis revealed strong positive associations (p < 0.01) among the chemical parameters and potentially toxic elements in soils, and demonstrated the lead-acid battery industry as the primary contamination source in the studied areas. There were strong positive relationships (p < 0.01) existed between As, Cd, and Zn in soils and vegetables; while a strong negative association found between As in soils with As in Fruits. The cluster analysis showed EC, OC, OM, Pb, As and Zn into separate group, implied their same source of origin as anthropogenic source. The metal uptake was in the decreasing order of Cd > Zn > As > Pb and Cd > Zn > Pb > As in vegetable and fruit samples, respectively and transfer factor analysis highlighted Cd and Zn as metals with higher absorption rates in vegetables and fruits. Among the industries, AA and AB were significantly impacted on soil quality, and considerable metal accumulation found on vegetables. The human health risk assessment results indicate a potential noncarcinogenic health hazard for the populations surrounding the industries (AA, AB, and AC). This is evidenced by the calculation of the total target hazard quotient and the hazard index, both of which exceeded the acceptable level (>1). However, the carcinogenic health risks arising from the consumption of potentially toxic elements are within threshold values. This study provides crucial insights into the environmental as well as health impact of lead-acid battery industries, emphasizing the urgency of implementing effective environmental management practices to mitigate their consequences.

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来源期刊
Environmental Nanotechnology, Monitoring and Management
Environmental Nanotechnology, Monitoring and Management Environmental Science-Water Science and Technology
CiteScore
13.00
自引率
0.00%
发文量
132
审稿时长
48 days
期刊介绍: Environmental Nanotechnology, Monitoring and Management is a journal devoted to the publication of peer reviewed original research on environmental nanotechnologies, monitoring studies and management for water, soil , waste and human health samples. Critical review articles, short communications and scientific policy briefs are also welcome. The journal will include all environmental matrices except air. Nanomaterials were suggested as efficient cost-effective and environmental friendly alternative to existing treatment materials, from the standpoints of both resource conservation and environmental remediation. The journal aims to receive papers in the field of nanotechnology covering; Developments of new nanosorbents for: •Groundwater, drinking water and wastewater treatment •Remediation of contaminated sites •Assessment of novel nanotechnologies including sustainability and life cycle implications Monitoring and Management papers should cover the fields of: •Novel analytical methods applied to environmental and health samples •Fate and transport of pollutants in the environment •Case studies covering environmental monitoring and public health •Water and soil prevention and legislation •Industrial and hazardous waste- legislation, characterisation, management practices, minimization, treatment and disposal •Environmental management and remediation
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