The Application of Heavy Metal Distribution and Pb Isotopic Ratios to Determine the Pollution Source of Surface Soils in Mashhad Parks

Document Type : Research Article

Authors

Payame Noor University

Abstract

Introduction
Anthropogenic activities have a high impact on urban areas and lead to severe pollution in large cities. Urban soils are huge ‘basins’ for accumulation of various pollutants. Thus, they also serve as informative media. Therefore, the study of urban soils has developed in recent years.
Mashhad is the second metropolitan city in Iran which has more than 3 million residences and over 20 million annual pilgrimage tourists. This city is surrounded by numerous factories and the high growth of urbanization has led to accelerated air pollution. In this research study, new analytical data for heavy metals (Cd, Co, Cr, Cu, Ni, Pb, Sn and Zn) in soil of parks in Mashhad are presented and they are compared with unpolluted non-urban soils. Then, the origin of soil pollution in park soils is discussed by statistical methods and Pb isotope values.
 
Materials and methods
The main aim of this work is to focus on the urban areas of Mashhad and study park soil geochemistry. Twenty three parks were selected for this purpose. At each selected park, top soils (5-20 cm) were collected. In addition to park samples, 4 soil samples were collected from areas which were far from the urban areas and they were considered to be unpolluted.
The concentration of heavy metals was defined by ICP-MS at the accredited Activation Laboratories (Actlabs.), Canada. To determine available and bioavailable fractions of Co, Cr and Ni, soil samples were analyzed by the DTPA method (Lindsay and Norvell, 1978). Pearson correlation coefficients and PCA are used to investigate elemental associations and extract latent factors for analyzing relationships among the observed variables. In this regard, these statistical analyses of park soils data were done with the SPSS 16.0 software package for Windows. The geochemical maps were plotted by a geographical information system (GIS) using ArcMap v.10.0 (ArcGIS) to show the overall spatial distribution patterns of total and available heavy metal concentrations. The Pb isotopes were measured in all samples by a ThermoFinnigan Neptune MC-ICP-MS instrument. Isotopic measurements were performed by the procedure proposed by Álvarez-Iglesias et al.’s (2012).
 
Results and discussion
Park soil samples have a higher concentration of heavy metals than non-urban soils. PCA analysis and Pearson correlation coefficient indicate that anthropogenic sources are the main factors controlling the Cd, Pb, Sn and Zn concentrations (PC1 component) in park soils. In other words, both anthropogenic and natural sources are responsible for Cr, Co and Ni (PC2 component) distribution in these soils. The spatial variation of heavy metals in the soil of parks in Mashhad confirm the statistical results and PC1 and PC2 heavy metals show different spatial variations. Furthermore, there is clear correlation between metals distributions, so that central parks generally have a higher content of all heavy metals which could be related to the heavy traffic and many traffic jams and air pollution in these areas.
The lead isotopic ratios of the sample studied show that park soils show a distinct composition from non-urban soils. These samples are less radiogenic than non-urban soils with lower 206Pb/204Pb, 207Pb/204Pb, 208Pb/204Pb, 206Pb/207Pb and higher 208Pb/206Pb ratios. The wide range of isotope ratios in park soils indicate that the Pb content in these soils is produced by the combination of different sources including natural and anthropogenic origins and that it has also been accumulating over time because of the enormous use of Pb in fuel, industrial activities, etc. (Galušková et al., 2014).  The low 206Pb/204Pb values in park soils confirm a possible anthropogenic origin from the use of fossil fuels. The three-end-member model was used to determine possible Pb sources in the soil of parks in Mashhad. The average contribution was 6.6% and 93.4% for natural and anthropogenic (industrial and leaded petrol) sources, respectively. The detailed investigation of Pb isotope and Pb content of soil of parks suggests that industrial source is the main origin of samples with relatively low Pb content ( 
Conclusion
The concentrations of potentially toxic elements in the soil of parks in the city of Mashhad are highly enriched relative to non-urban soils. The Pb isotope composition of non-urban soils indicate that they have a natural source while park soil samples have originated from anthropogenic sources. The soils which are sampled from the central parks of Mashhad have shown the highest heavy metal pollution due to high traffic congestion in these areas.
 
References
Álvarez-Iglesias, P., Rubio, B. and Millos, J., 2012. Isotopic identification of natural vs. anthropogenic lead sources in marine sediments from the inner Ría de Vigo (NW Spain). Science of the Total Environment, 437‌(1): 22–35.
Galušková, I., Mihaljevič, M., Borůvka, L., Drábek, O., Frühauf, M. and Němeček, K., 2014. Lead isotope composition and risk elements distribution in urban soils of historically different cities Ostrava and Prague, the Czech Republic. Journal of Geochemical Exploration, 147‌(3): 215–221.
Lindsay, W.L. and Norvell, W.A., 1978. Development of a DTPA soil test for zinc, iron, manganese, and copper. Soil Science Society of America Journal, 42‌(3): 421–428.

Keywords

References

Alavi, M., 1991. Sedimentary and structural characteristics of the Paleo-Tethys remnants in northeastern Iran. Geological Society of America Bulletin, 1038(1): 983–992.
Alexander, E.B., 2004, Serpentine soil redness, differences among peridotite and serpentinite materials, Klamath Mountains, California. International Geoloy Review, 46(8): 754–764.
Álvarez-Iglesias, P., Rubio, B. and Millos, J., 2012. Isotopic identification of natural vs. anthropogenic lead sources in marine sediments from the inner Ria de Vigo (NW Spain). Science of the Total Environment, 437(1): 22–35.
Argyraki, A. and Kelepertzis, E., 2014. Urban soil geochemistry in Athens, Greece: The importance oflocal geology in controlling the distribution of potentially harmfultrace elements. Science of the Total Environment 482–483(2): 366–377.
Ault, W.U., Senechal, R.G. and Erlebach, W.E., 1970. Isotopic composition as a natural tracer of lead in the environment. Environmental Science and Technology, 4(3): 305–313.
Bourliva, A., Papadopoulou, L., Aidona, E. and Giouri, K., 2017. Magnetic signature, geochemistry, and oral bioaccessibility of “technogenic” metals in contaminated industrial soils from Sindos Industrial Area, Northern Greece. Environmental Science and Pollution Research, 24(8): 17041–17055.
Chabukdhara, M. and Nema, A.K., 2013. Heavy metals assessment in urban soil around industrial clusters in Ghaziabad, India: Probabilistic health risk approach. Ecotoxicology and Environmental Safety, 87(1): 57–64.
Cheng, H. and Hu, Y., 2010. Lead (Pb) isotopic fingerprinting and its applications in lead pollution studies in China: a review. Environmental Pollution, 158(10): 1134–1146.
Chrastny, V., Vaněk, A., Teper, L., Cabala, J., Proch'azka, J. and Pechar, L., 2012. Geochemical position of Pb, Zn and Cd in soils near the Olkusz mine/smelter, South Poland: effects of land use, type of contamination and distance from pollution source. Environmental Monitoring and Assessment, 184(12): 2517–2536.
Civitillo, D., Ayuso, R.A., Lima, A., Albanese, S., Esposito, R., Cannatelli, C. and De Vivo, B., 2016. Potentially harmful elements and lead isotopes distribution in a heavily anthropized suburban area: the Casoria case study (Italy). Environmental Earth Sciences, 75(1): 1325–1342.
Doe, B.R. and Delevaux, M.H., 1972. Source of lead in Southeast Missouri galena ores. Economic Geology, 67(4): 409–425.
Faure, G., 1986. Principles of Isotope Geology. Wiley, New York, 589 pp.
Galuškova, I., Mihaljevič, M., Borůvka, L., Drabek, O., Frühauf, M. and Němeček, K., 2014. Lead isotope composition and risk elements distribution in urban soils of historically different cities Ostrava and Prague, the Czech Republic. Journal of Geochemical Exploration, 147(3): 215–221.
Gu, Y.G., Gao, Y.P. and Lin, Q., 2016. Contamination, bioaccessibility and human health risk of heavy metals in exposed-lawn soils from 28 urban parks in southern China's largest city, Guangzhou. Applied Geochemistry, 67(1): 52–58.
Han, L., Gao, B., Wei, X., Gao, L., Xu, D. and Sun, K., 2015. The characteristic of Pb isotopic compositions in different chemical fractions in sediments from Three Gorges Reservoir. China Environmental Pollution, 206(5): 627–635.
Hansmann, W. and Kӧppel, V., 2000. Lead-isotopes as tracers of pollutants in soils, Chemical Geology, 171(1): 123–144.
Hooda, P.S., 2010. Trace elements in soils. Wiley, New York, 616 pp.
Hormozi Nejad, F., Rastmanesh, F. and Zarasvandi, A.R., 2016. Contamination assessment of heavy metals in the soils around Khouzestan Steel Company (KSC) (Ni, Mn, Pb, Fe, Zn, Cr). Journal of Economic Geology, 8(2): 415–429. (in Persian with English abstract)
Karimi, A., Haghnia, G.H., Safari, T. and Hadadian, H., 2017. Lithogenic andanthropogenic pollution assessment of Ni, Zn and Pb in surface soils of Mashhad plain, northeastern Iran. Catena, 157(1):151–162.
Karimpour, M.H., Malekzadeh Shafaroudi, A. and Saadat, S., 2014. Mineralogy, geochemistry, genesis, and industrial application of silica in Arefi area, south of Mashhad. Journal of Economic Geology, 6(2): 259–276. (in Persian with English abstract)
Komarek, M., Ettler, V., Chrastny, V. and Mihaljevic, M., 2008. Lead isotopes in environmental sciences: a review. Environmental International, 34(6): 562–577.
Li, X., Lee, S.I., Wong, S.C., Shi, W. and Thornton, I., 2004. The study of metal contamination in urban soils of Hong Kong using a GIS-based approach. Environmental Pollution, 129(1): 113–124.
Li, H.., Yu, S., Li, G.., Deng, H. and Luo, X., 2011. Contamination and source differentiation of Pb in park soils along an urban–rural gradient in Shanghai. Environmental Pollution, 159(4): 3536–3344.
Lindsay, W.L. and Norvell, W.A., 1978. Development of a DTPA soil test for zinc, iron, manganese, and copper. Soil Science Society of America Journal, 42(3): 421–428.
Liu, Z., Pan, S., Sun, Z., Ma, F., Chen, L., Wang, Y. and Wang, S., 2015. Heavy metal spatial variability and historical changes in the Yangtze River estuary and North Jiangsu tidal flat. Marian Pollution Bulletin, 98(1): 115–129.
Loska, K. and Wiechuya, D., 2003. Application of principle component analysis for the estimation of source of heavy metal contamination in surface sediments from the Rybnik Reservoir. Chemosphere, 51(4): 723–733.
Mazhari, S.A., Mazloumi Bajestani, A.R. and Sharifiyan Attar, R., 2013. Geochemical investigation of Davarzan surface soils, west of Sabzevar, NE Iran. Iranian Journal of Earth Sciences, 5(1): 43–53.
Mazhari, S.A., Sharifiyan Attar, R. and Haghighi, F., 2017, Heavy metals concentration and availability of different soils in Sabzevar area, NE of Iran. Journal of African Earth Sciences, 134(1): 106–112.
Mazhari, S.A., Mazloumi Bajestani, A.R., Hatefi, F., Aliabadi, K. and Haghighi, F., 2018. Soil geochemistry as a tool for the origin investigation and environmental evaluation of urban parks in Mashhad city, NE of Iran. Environmental Earth Sciences, 77(13): 1–17.
Mirnejad, H., Lalonde, A.E., Obeid, M. and Hassanzadeh, J., 2013. Geochemistry and petrogenesis of Mashhad granitoids: An insight into the geodynamic history of the Paleo-Tethys in northeast of Iran. Lithos, 170–171(1): 105–116.
Monna, F., Aiuppa, A., Varrica, D. and Dongarra, G., 1999. Pb isotope composition in lichens and aerosols from eastern Sicily: insights into the regional impact of volcanoes on the environment. Environmental Science and Technology, 33(11): 2517–2523.
Razavi, M.H., Masoudi, F. and Alaminia, Z., 2008. Garnet–biotite chemistry for thermometry of staurolite schist from south of Mashhad, NE Iran. Journal of Sciences, Islamic Republic of Iran, 19(2): 237–245.
Reid, M.K. and Spencer, K.L. 2009. Use of principal components analysis (PCA) on estuarine sediment datasets: the effect of data pre-treatment. Environmental Pollution, 157(8–9): 2275–2281.
Rodriguez-Seijo, A., Arenas-Lago, D., Andrade, M.L. and Vega, F.A., 2015. Identifying sources of Pb pollution in urban soils by means of MC-ICP-MS and TOF-SIMS. Environmental Science and Pollution Research, 22(14): 7859–7872.
Sharma, R.K., Agrawal, M. and Marshall, F.M., 2009. Heavy metals in vegetables collected from production and market sites of a tropical urban area of India. Food and Chemical Toxicology, 47(4): 583–591.
Sun, Y., Zhou, Q., Xie, X. and Liu, R., 2010. Spatial, sources and risk assessment of heavy metal contamination of urban soils in typical regions of Shenyang, China. Journal of Hazardous Materials, 174(3): 455–462.
Taheri, J. and Ghaemi, F., 1994. Geological map of Mashhad, scale 1:100000. Geological survey of Iran.
Yang, Z., Lu, W., Long, Y., Bao, X. and Yang, Q., 2011. Assessment of heavy metals contamination in urban topsoil from Changchun City, China. Journal of Geochemical Exploration, 108(1): 27–38.
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 09 January 2018
  • Accept Date: 26 February 2019

Share

How to cite

Statistics