توزیع مکانی جیوه در خاک‌های اطراف کارخانه سیمان کرمان

نوع مقاله : مقالات پژوهشی

نویسندگان

1 صنعتی اصفهان/پیام نور اصفهان

2 دانشگاه شهید باهنر کرمان

چکیده

خاک­ها به دلیل دریافت رسوبات، شاخص­های معتبری از پدیده آلودگی هستند. اطلاعات کمی در زمینه توزیع جیوه در خاک­های مناطق صنعتی بویژه در ایران موجود است. به منظور بررسی توزیع مکانی جیوه و همچنین وسعت آلودگی جیوه در خاک، مطالعه­ای در خاک­های اطراف کارخانه سیمان کرمان طراحی و اجرا گردید. تعداد 103 نمونه خاک سطحی جمع­آوری و غلظت کل جیوه خاک تعیین گردید. شاخص­های ارزیابی میزان آلودگی، محاسبه و نقشه­های پراکنش مکانی جیوه تهیه شد. همچنین نقش فاکتورهای محیطی در توزیع جیوه بررسی گردید. غلظت کل جیوه در خاک در محدوده 7/6 تا 341 میکروگرم در کیلوگرم با میانگین 1/164 میکروگرم در کیلوگرم به دست آمد. مقایسه مقادیر این عنصر با میانگین جهانی آن در خاک­ها نشان می­دهد فعالیت­های صنعتی در منطقه باعث افزایش غلظت جیوه در خاک شده است. نتایج حاصل از شاخص زمین انباشتگی نمونه­های خاک نشان داد که خاک­های مورد مطالعه از نظر آلودگی جیوه در محدوده غیرآلوده تا آلودگی متوسط و براساس فاکتور آلودگی، سطوح آلودگی کم تا آلودگی قابل ملاحظه جیوه مشخص گردید. نقشه توزیع مکانی غلظت کل جیوه نشان می­دهد بیشترین غلظت جیوه در اطراف کارخانه و به سمت جنوب و جنوب شرقی منطقه مشاهده می­شود. غلظت­های بالای جیوه در مناطق کم ارتفاع و کم شیب روی شیب جنوبی منطقه مشاهده می­شود. نتایج نشان داد هر چند غلظت این آلاینده در منطقه مورد مطالعه حاد نمی باشد ولی با توجه به نزدیک بودن منطقه صنعتی به محل مسکونی، برنامه­ریزی جهت کنترل انتشار این فلز و آلاینده­های دیگر باید مورد توجه جدی قرار گیرد.

کلیدواژه‌ها


عنوان مقاله [English]

Spatial Distribution of Mercury Contamination in Soils around of Kerman Cement Plant

نویسندگان [English]

  • Maryam Yousefifard 1
  • A. Jafari 2
2 Kerman
چکیده [English]

Introduction: In recent decades, industrial and technological advancements have led to the gradual increase of heavy metal concentrations. As such, this phenomenon of heavy metals being present in the environment at high concentrations causes deleterious effects on various terrestrial creatures and human beings. Mercury (Hg) is one of the most toxic elements and can cause renal and neurotoxicity to humans and wildlife. It has been identified as a priority toxic substance in many countries. It is, however, rare to find information on Hg in soils from industrialized areas of Iran in literature. In order to ascertain the distribution of Hg, as well as the extent of contamination with Hg, and to provide policymakers with remediation measures for the affected soils, a study of surface soils was conducted in areas around of Kerman cement plant.
Materials and Methods: Soil samples were collected from the depth of 0 to 20 cm. 103 samples were taken and analyzed. Mercury concentration in soil samples were determined by atomic adsorption method coupled Graphite furnace. Statistical analysis and indices calculation were performed by SPSS and EXCEL, respectively, and distribution maps were prepared by kriging method in ArcGIS software. For evaluating pollution, Geoaccumulation index, enrichment factor and contamination factor were also calculated and interpreted.
Results and Discussion: The mercury concentration in soil samples ranged from 6.70 to 340.96 μg/kg, with a mean value of 164.06 μg/ kg. Mercury is naturally present in very low concentrations in the soil. The concentration of this element in soils ranges from 0.01 to 0.5 mg/kg around the world. The average Hg concentration in the earth crust is reported to be 80 μg / kg. In soils of the study area, the Hg concentration was higher than most of the reported values for soils worldwide and earth crust. This indicates that industrial activities have increased the concentration of mercury in the soil. In fact, the concentration of mercury more than the amount of earth crust indicates the onset of contamination due to various anthropogenic activities. The coefficient of variation of mercury concentration in the soil was 55%, which shows a high variability (CV≥ 35%) according to the classification proposed by Wilding et al. (19). The high variability coefficient shows the heterogeneous and non-uniform distribution of the property. Therefore, there is a high concentration of mercury in some areas of the study region. In other words, soil was affected by external factors in some areas. Based on the cleaning standards of soil for mercury in soils used for industrial purposes in some countries, all soil samples in the studied area have a much lower concentration of mercury than standard values. In other words, although the activity of the cement plant has increased the concentration of mercury in the soil, it can continue its industrial activity. The plant’s managers should, however, take a close look at the release of this metal and other pollutant. According to the results derived from Igeo, Hg was graded as unpolluted to moderately polluted. Low levels of contamination (CF <1) to significant contamination (3.00 ≤ CF <6.00) of mercury were observed based on the contamination factor. The results suggest that anthropogenic sources control the concentration of mercury in the soil. The average contamination factor more than one (CF> 1) indicates that the soils of this region have been exposed to mercury contamination. Spatial distribution map indicates that the highest concentration of mercury in the soil is between 200 and 341 μg/kg, which was observed around the factory and south-east of the region. Release of mercury in the environment is related to natural processes and human activities. Mercury release due to human activities is mainly due to combustion of fossil fuels, iron ore processing, steel industry and cement plants. Considering the high concentrations of mercury in the southeastern part of the region, the lower part of the plant, it seems that environmental factors such as the topography of the area may affect its distribution. The high concentrations of Hg were observed at low elevations, on the south side, and over the areas with relatively low slope gradients.
Conclusion: The results demonstrated that the concentration of Hg was higher than most of the reported values for soils worldwide and earth crust. This indicates that industrial activities have increased the concentration of mercury in the soil. According to the results derived from Igeo, Hg was graded as unpolluted to moderately polluted. In addition, the level of contamination was identified to be low to high, based on the contamination factor (CF). The spatial distribution map of the total concentration of mercury shows that the highest concentration of mercury was observed around the factory and to the south and southeast of the region. The high concentrations of this metal were at low elevations and on the south side of the catchment and in areas with relatively low slope gradients. It is concluded that although the concentration of this pollutant is not critical in the study area, due to the close proximity of the industrial area to the residential area, planning to control the release of this metal and other pollutants should be seriously considered.
 

کلیدواژه‌ها [English]

  • Cement factory
  • Environment variables
  • Hg concentration
  • Pollution index
1- Adriano D.C. 1986. Trace Elements in the Terrestrial Environment. New York: Springer-Verlag; 533p.
2- Airey D. 1982. Contributions from coal and industrial materials to mercury in air, rainwater and snow. Science of Total Environment 25: 19-40.
3- Bahuiyan M.A.H., Parvez L., Islam M.A., Dampare S.B., and Suzuki S. 2010. Heavy metal pollution of coal mine-affected agricultural soils in the northern part of Bangladesh. Journal of Hazardous Materials 173(1-3): 384-392.
4- Boszke L., and Kowalski A. 2006. Spatial Distribution of Mercury in Bottom Sediments and Soils from Poznań, Poland.Polish. Journal of Environment Studies 15(2): 211-18.
5- Conko K.M., Landa E.R., Kolker A., Kozlov K., Gibb H.J., Centeno J.A., and B.S Panov Y.B. 2013. Arsenic and mercury in the soils of an industrial city in the Donets basin, Ukraine. Soil and Sediment Contamination 22: 574–93.
6- Crock J.G. 1999. Mercury. p. 769-792. In A.L. Page et al. (ed.) Methods of Soil Analysis. Part 3. 2nd ed. Agron. Monogr. 9. ASA and SSSA, Madison, WI.
7- De Bartolomeo A., Poletti L., Sanchini G., Sebastiani B., and Morozzi G. 2004. Relationship among parameters of lake polluted sediments evaluated by multivariate statistical analysis. Chemosphere 55(10): 1323–29.
8- Duan X., Zhang G., Rong L., Fang H., He D., and Feng D. 2015. Spatial distribution and environmental factors of catchment-scale soil heavy metal contamination in the dry-hot valley of Upper Red River in southwestern China. Catena 135: 59-69.
9- Fukuzaki N., Tamura R., Hirano Y., and Mizushima Y. 1986. Mercury emission from a cement factory and its influence on the environment. Atmospheric Environment 20(12): 2291-2299.
10- Kheirabadi H. 2011. Investigation of the origin of heavy elements in soil and their risk assessment on human health in surface soils of Hamadan province. Thesis Master of Science in Soil Science, Faculty of Agriculture, Isfahan University of Technology.
11- Luo W., Yonglong L., Bin W.,·Xiaojuan T., Guang W., Yajuan S,·Tieyu W., and John P.G. 2009. Distribution and sources of mercury in soils from former industrialized urban areas of Beijing, China. Environmental Monitoring of Assessment 158: 507-571.
12- Meza-Montenegro M.M., Gandolfi A.J., Santana-Alcanter M.E., Klimecki W.T., Aguilar-Apodaca M.G., Rio-Salas R.D., O-Villanueva M.D.L., Gomez-Alvarez A., Mendivil-Quijada H., Valencia H., and Meza-Figueroa D. 2012. Metals in residential soils and cumulative risk assessment in Yaqui and Mayo agricultural valleys, northern Mexico. Science of the Total Environment 433: 472-481.
13- Mizanur Rahman G.M., and Skip Kingston H.M. 2005. Development of a microwave-assisted extraction method and isotopic validation of mercury species in soils and sediments. Journal of Analytical Atomic Spectrometry 20: 183–191.
14- Mniszek W. 1996. Emission of mercury to the atmosphere from industrial sources in Poland. Environmental Monitoring and Assessment 41: 291.
15- Muller G. 1969. Index of geoaccumulation in sediments of the Rhine River. Geojournal 2: 108-118.
16- Provoost J., Cornelis C., and Swartjes F. 2006. Comparison of soil clean-up between countries: Why do they differ? Journal of Soils standards for trace elements and Sediments 6: 173–181.
17- Sergio A., Covarrubias S.A., Armando Flores de la Torre J., Maldonado Vega M., Francisco Javier Avelar Gonzalez F.J., and Cabriales J.J.P. 2018. Spatial Variability of Heavy Metals in Soils and Sediments of “La Zacatecana” Lagoon, Mexico. Applied and Environmental Soil Science ID 9612412, 8 pages.
18- Solgi E., Esmaili Sari A., and Riyahi Bakhtiari A. 2013. Evaluation of mercury contamination in soils of industrial estates of Arak city. Journal of Health in the Field 1(2): 22-28.
19- Taylor S.R., and McLennan S.M. 1995. The geochemical evolution of the continental crust. Review Geophysics 33: 165–241.
20- Wilding L., Drees L.R., and Nordt L.C. 2001. Spatial variability: enhancing the mean estimate of organic and inorganic carbon in a sampling unit. p. 69-85. In: Lal, R., Kimble, J.M., Follett, R.F., Stewart, B.A., (ed.), Assessment Methods for Soil Carbon, CRC/Lewis Publishers, Boca Raton, FL.
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دوره 34، شماره 1 - شماره پیاپی 69
فروردین و اردیبهشت 1399
صفحه 85-95
  • تاریخ دریافت: 22 اسفند 1397
  • تاریخ بازنگری: 13 شهریور 1398
  • تاریخ پذیرش: 07 دی 1398
  • تاریخ اولین انتشار: 01 فروردین 1399