Heavy metals assessment and identification of their sources in agricultural soils of Southern Tehran, Iran

Hani, Abbas; Pazira, Ebrahim

doi:10.1007/s10661-010-1612-3

Cited by 103 publications

(46 citation statements)

References 35 publications

(42 reference statements)

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“…The metals in PC 1 were mainly derived from non-anthropogenic sources, indicating local natural sources. The most important sources of Cd in the arable soils of suburban areas are the long-term application of fertilizers, sewage sludges, and organic manures (Zhang, 2006;Hani and Pazira, 2011). Cr and Ni in PC 2 were strongly correlated with each other and were clearly separated from the other heavy metals regarding their correlation coefficient analysis and PCA.…”

Section: Principal Component Analysis Of Soil Heavy Metalsmentioning

confidence: 98%

“…The main sources of heavy metals may include various anthropogenic activities such as industry, mining, atmospheric deposition, excessive application of chemical fertilizers and pesticides, and sewage and wastewater irrigation (Wilson and Pyatt, 2007;Khan et al, 2008;Wang et al, 2013). Heavy metals can enter plant tissues by uptake from contaminated soils, wastewater irrigation and atmospheric deposition (Huang et al, 2007;Sridhara Chary et al, 2008;Hani and Pazira, 2011;Wang et al, 2013).…”

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confidence: 99%

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Concentrations of Heavy Metals in Suburban Horticultural Soils and Their Uptake by Artemisia selengensis

Cui

Sun

et al. 2015

Pedosphere

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A total of 222 surface soil samples and 40 plant samples were collected to investigate the spatial distribution and possible sources of soil heavy metals and to know the uptake and translocation of heavy metals from roots to different plant parts in a representative vegetable production area in the Baguazhou Island, a suburb of Nanjing City, East China. The arithmetic mean values of total Cd, Cr, Cu, Ni, Pb, and Zn concentrations in the soils were 0.314, 133, 41.0, 58.0, 31.8, and 114 mg kg −1 , respectively. All of these values were above the topsoil background values in the Nanjing area. Multivariate and geostatistical analyses showed that soil Cd contamination was derived mainly from agricultural practices. In contrast, Cu and Zn were derived mainly from soil parent materials and Pb from atmospheric deposition from highway gasoline stations. Artemisia selengensis, a locally important specialty vegetable, accumulated heavy metals primarily in the edible leaves. The general distribution of heavy metal concentrations in this plant species showed that the highest occurred in the leaves, intermediate in the stems and lowest in the roots. Cd had the highest concentration factor (root-to-soil ratio) and may pose increased health risks in the future to the local population through the consumption of contaminated vegetables.Key Words: concentration factor, plant uptake, pollution source, spatial distribution, translocation factor, vegetable Citation: Cui X, Sun X L, Hu P J, Yuan C, Luo Y M, Wu L H, Christie P. 2015. Concentrations of heavy metals in suburban horticultural soils and their uptake by Artemisia selengensis. Pedosphere. 25(6): 878-887.

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Section: Principal Component Analysis Of Soil Heavy Metalsmentioning

confidence: 98%

mentioning

confidence: 99%

Concentrations of Heavy Metals in Suburban Horticultural Soils and Their Uptake by Artemisia selengensis

Cui

Sun

et al. 2015

Pedosphere

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“…In this process plants uptake the contaminants by roots and accumulate in the aerial parts or shoots of (Bissen and Frimmel 2003 ;Walsh et al 1979 ) 2 Cu Timber treatment, fertilizers, fungicides, electroplating industry, smelting and refi ning, mining, biosolids (Liu et al 2005 ) 3 Cd Anthropogenic activities, smelting and refi ning, fossil fuel burning, application of phosphate fertilizers, sewage sludge (Alloway 1995 ;Kabata-Pendias 2001 ) 4 Pb Batteries, metal products, mining and smelting of metalliferous ores, burning of leaded gasoline, municipal sewage, industrial wastes enriched in Pb, paints (Gisbert et al 2003 ;Seaward and Richardson 1990 ) 5 Cr Timber treatment, leather tanning, pesticides and dyes, electroplating industry (Knox et al 1999 ;Gowd et al 2010 ) 6 Hg Fumigants and fertilizers, volcano eruptions, forest fi re, emissions from industries producing caustic soda, coal, peat, and wood burning (Lindqvist 1991 ) 7 Zn Dyes, paints, timber treatment, fertilizers and mine tailings, electroplating industry, smelting and refi ning, mining (Liu et al 2005 ) 8 Ni Alloys, batteries and mine tailings, volcanic eruptions, land fi ll, forest fi re, bubble bursting, and gas exchange in ocean (Knox et al 1999 ) 9 Cd, Pb, and As Over application of fertilizers and pesticides (Atafar et al 2010 ) 10 Pb Commercial organic fertilizer (Wang et al 2013 ) 11 Cd, Cu, Ni, and Zn Urban and industrial wastewater used in agricultural practices (Hani and Pazira 2011 ) the plant and fi nally it is harvested and disposed of (Vishnoi and Srivastava 2007 ). The plant-based remediation technology is one of the largest technologies to remediate the heavy metal pollution from the environment (Raskin et al 1997 ).…”

Section: Phytoextractionmentioning

confidence: 99%

Phytoremediation of Heavy Metals: The Use of Green Approaches to Clean the Environment

Singh

Santal

2015

Phytoremediation

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“…Statistical (Hani and Pazira 2011) and geochemical methods including enrichment factor (Anderson and Kravitz 2010), sequential extractions (Zimmerman and Weindorf 2010), geochemical relationships (Bourennane et al 2010) and geochemical mapping (Reimann and de Caritat 2005), among other methods, have been used for the assessment of heavy metal contamination in soils. Since these methods are based on assumptions of reference values for natural contents, there is always considerable range and discrepancies in the assessed soil contamination results from single application of each and every one of the methods.…”

Section: Introductionmentioning

confidence: 99%

Multivariate Mapping of Heavy Metals Spatial Contamination in a Cu–Ni Exploration Field (Botswana) Using Turning Bands Co-simulation Algorithm

2018

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With a mining-driven economy, Botswana has experienced increased geochemical exploration of minerals around existing mining towns. The mining and smelting of copper and nickel around Selibe-Phikwe in the Central Province are capable of releasing heavy metals including Pb, Fe, Mn, Co, Ni and Cu into the soil environments, thereby exposing humans, plants and animals to health risks. In this study, turning bands co-simulation, a multivariate geostatistical algorithm, was presented as a tool for spatial uncertainty quantification and probability mapping of cross-correlated heavy metals (Co, Mn, Fe and Pb) risk assessment in a semiarid Cu-Ni exploration field of Botswana. A total of 1050 soil samples were collected across the field at a depth of $ 10 cm in a grid sampling design. Rapid elemental concentration analysis was done using an Olympus Delta Sigma portable X-ray fluorescence device. Enrichment factor, geoaccumulation index and pollution load index were used to assess the potential risk of heavy metals contamination in soils. The partially heterotopic nature of the dataset and strong correlations among the heavy metals favors the use of co-simulation instead of independent simulation in the probability mapping of heavy metal risks in the study area. The strong correlation of Co and Mn to iron infers they are of lithogenic origin, unlike Pb which had weak correlation pointing to its source in the area being of anthropogenic source. Manganese, Co and Fe show low enrichment, whereas Pb had high enrichment suggesting possible lead pollution. We, however, recommend that speciation of Pb in the soils rather than total concentration should be ascertained to infer chances of possible bioaccumulation, and subsequent health risk to human by chronic exposure.

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Heavy metals assessment and identification of their sources in agricultural soils of Southern Tehran, Iran

Cited by 103 publications

References 35 publications

Concentrations of Heavy Metals in Suburban Horticultural Soils and Their Uptake by Artemisia selengensis

Concentrations of Heavy Metals in Suburban Horticultural Soils and Their Uptake by Artemisia selengensis

Phytoremediation of Heavy Metals: The Use of Green Approaches to Clean the Environment

Multivariate Mapping of Heavy Metals Spatial Contamination in a Cu–Ni Exploration Field (Botswana) Using Turning Bands Co-simulation Algorithm

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