Investigation of Heavy Metals Accumulation in Plants Growing in Contaminated Soils (Case Study: Qazvin Province, Iran)
الموضوعات :
Mahdieh Ebrahimi
1
(Faculty of Water and Soil Science, University of Zabol.)
Mohammad Jafari
2
(Faculty of Natural Resources, University of Tehran)
Gholam Reza Savaghebi
3
(Faculty of Agriculture, University of Tehran)
Hossein Azarnivand
4
(Faculty of Natural Resources, University of Tehran)
Ali Tavili
5
(Faculty of Natural Resources, University of Tehran)
Fernando Madrid
6
(Titled Superior Specialized, IRNAS-CSIC)
الکلمات المفتاحية: Heavy metals, phytoremediation, BCF, TF, Lia industrial city,
ملخص المقالة :
Environmental pollution with heavy metals is a global disaster that is related tohuman activities. This study was conducted to determine the extent of heavy metalsaccumulation by plant species in Lia industrial city (Qazvin, Iran) and to investigate theremediative capacity of native plant species grown in the contaminated soils. Soil andindustrial wastewater sampling was done radially along transects with 300 m intervalsfrom exit point of wastewater at three sites. In each sampling point, along 100 m transectswithin 5×2 m plots, the plant samples and soil samples were collected in depth of 0-20 cmand 20-40 cm from rhizosphere zone. Concentration of copper, zinc and chromium in rootand shoot of 11 plant species, soil and wastewater were analyzed in three sits formentioned metals. Bio Concentration factors and translocation factor were determined toensure phytoremediation availability. Results showed that the concentrations of metals inthe soil and wastewater greatly exceeded the threshold limit values. The contents of metalsin soils ranged in the order of Cr>Zn>Cu and in wastewater were in the order ofZn>Cr>Cu, respectively. Results showed that Scirpus maritimus L. and Phragmitesaustralis (Cav.) Trin. ex Steudel presented the highest accumulation of Zn, Cu and Cr intheir root tissues which were suitable for phytostabilization (with a high BCF couple withlow TF). The lowest extractable Zn (7.24 and 3.29 mgkg-1 for shoot and root respectively,BCF=0.07) and extractable Cu (2.56 and 2.80 mgkg-1 for shoot and root respectively,BCF=0.14) were related to Hordeum glaucum L. Moreover, the relatively lowest values ofCr were measured for Taraxacum officinale L. Results indicated that the species, whichhad low metal bioaccumulation in their roots and high TF, could play important roles forremoval of heavy metals through phytoextraction.
Abdel-Ghani, N. T., Hefny, M., and El-Chagbaby, G. A. F., 2007. Removal of lead from aqueous solution using low cost abundantly available adsorbents. Jour. Envir. Sci. Tech. 41: 67-73.
Alloway, B. J., 1990. Heavy metals in soils. Glasgow, UK: Blackie and Son. p. 384.
Alloway, B. J., Jackson, A. P., and Morgan, H., 1990. The accumulation of cadmium by vegetables grown on soils contaminated from a variety of sources. Sci. Envir. Jour. 91: 223–236.
Antosiewicz, D. M., Escude-Duran, C., Wierzbowska, E., and Sklodowska, A., 2008. Indigenous plant species with the potential for the phytoremediation of arsenic and metals contaminated soil. Jour. Water Air Soil Pollution. 193: 197–210.
Ashraf, M. A., Maah, M. J., and Yusoff, I., 2011. Heavy metals accumulation in plants growing in ex tin mining catchment. Jour. Envir. Sci. Tech. 8(2): 401-416.
Baker, A. J. M., 1981. Accumulators and excluders strategies in the response of plants to heavy metals. Jour. Plant Nutrition. 31(4): 643-654.
Baker, A. J. M., and Brooks, R. R., 1989. Terrestrial higher plants which hyper-accumulate metallic elements. A review of their distribution, ecology and phytochemistry. Biorecovery. 1: 81-126.
Black, C. A., 1965. Methods of soil chemical analysis and microbiological properties. Agronomy No. 9. American Society of Agronomy, Madison.
Bodar, C. W., Pronk, M. E., and Sijm, D. T., 2006. The European Union risk assessment on zinc and zinc compounds: the process and the facts. Jour. Integ. Envir. Asses. Manag. 1: 301–319.
Bonanno, G., Lo Giudice, R., 2010. Heavy metal bioaccumulation by the organs of Phragmites australis common reed and their potential use as contamination indicators. Jour. Ecol. Indicators. 10: 639–645.
Bower, C. A., and Hatcher, J. T., 1966. Simultaneous determination of surface area and cation-exchange capacity. Soil Sci. Soc. Am. Proc. 30: 525-527.
Bragato, C., Brix, H., and Malagoli, M., 2006. Accumulation of nutrients and heavy metals in Phragmites australis (Cav.) Trin. ex Steudel and Bolboschoenus maritimuss (L.) Palla in a constructed wetland of the Venice lagoon watershed. Jour. Envir. Pollution, 144: 967–975.
Chehregani, A., Noori, M., and LariYazdi, H., 2009. Phytoremediation of heavy metal polluted soils: Screening for new accumulator plants in Angouran mine Iran and evaluation of removal ability. Jour. Ecotoxi. Envir. Safe. 72: 1349–1353.
Du Laing, G., Tack, F. M. G., and Verloo, M. G., 2003. Performance of selected destruction methods for the determination of heavy metals in reed plants Phragmites australis. Jour. Analyt. Chim. Acta. 49: 191–198.
Fitzgerald, E. J., Caffrey, J. M., Nesaratnam, S. T., and Mc Loughlin. P., 2003. Copper and lead concentrations in salt mash plants on the Suir Estuary, Ireland. Jour. Envir. Pollution, 123: 67-74.
Fotakis, G, and Timbrell, J. A., 2006. Role of trace elements in cadmium chloride uptake in hepatoma cell lines. Jour. Toxicol letters. 164: 97-103.
Ghosh, M., and Singh, S. P., 2005. A review on phytoremediation of heavy metals and utilization of its byproducts. Appl. Jour. Ecol. Envir. Res. 3: 1-18.
Greger, M, and T, Landberg. 1999. Use of willow in phytoremediation. Inter. Jour. Phyto. 12: 115-123.
Hansel, C., Fendorf, S., Sutton, S., and Newville, M., 2001. Characterization of Fe plaque and associated metals on the roots of mine-waste impacted aquatic plants. Jour. Envir. Sci. Tech. 35: 3863-3868.
Hernandez-Ochoa, I., Garcia-Vargas, G., Lopez-Carrillo, L., Rubio-Andrade, M., Moran-Martìnez, J., Cebrian, M. E., and Quintanilla-Vega, B., 2005. Low lead environmental exposure alters semen quality and sperm chromatin condensation in northern Mexico. Reprod. Toxicol. 20: 221–228.
Joner, E. J., and Leyval, C., 2001. Influence of arbuscular mycorrhiza on clover and ryegrass grown together in a soil spiked with polycyclic aromatic hydrocarbons. Jour. Mycorrhiza. 10: 155–159.
Kabata-Pendias, A., 2001. Trace elements in soils and plants. 3rd ed. LLC, Boka Raton, FL: CRC Press.
Khan, S., Ahmad, I., Tahir Shah, M., Rehman, S., and Khaliq, A., 2009. Use of constructed wetland for the removal of heavy metals from industrial wastewater. Jour. environ manage. 90(7): 3451-3457.
Lasat, M. M., 2002. Phytoextraction of toxic metals, a review of biological mechanisms. Jour. Envir. Quality. 31: 109–120.
Loeppert, R. H., and Suarez, D. L., 1996. Carbonate and gypsum. In Methods of Soil Analysis, part 3, Chemical Methods, Bigham JM and Bartels JM ed. SSSA, ASA, Madison, Wisconsin, Etatus-Unis, 437-474.
Mattina, M. J., Lannucci-Berger, W., Musante, C., and White, J. C., 2003. Concurrent plant uptake of heavy metals and persistent organic pollutants from soil. Jour. Envir. Pollution. 124: 375-378.
Nouri, J., Lorestani, B., Yousefi, N., Khorasani, N., Hasani., A. H., Seif, F.,and Cheraghi, M., 2011. Phytoremediation potential of native plants grown in the vicinity of Ahangaran lead–zinc mine Hamedan, Iran. Jour. Envir. Earth Sci. 62(3): 639-644.
Ok, Y. S., Usman, A. R. A., Lee, S. S., Abd El-Azeem, S. A. M., Choi, B. S., Hashimoto, Y., and Yang, J. E., 2011. Effects of rapeseed residue on lead and cadmium availability and uptake by rice plants in heavy metal contaminated paddy soil. Jour. Chemosphere. 85: 677–682.
Rowell, D. L., 1993. Soil Science: Methods and Applications. Longman, Harlow, Essex.
Salt, D. E., Blaylock, M., Kumar, N. P. B. A., Dushenkov, V., Ensley, B. D., Chet, I., and Raskin, I., 1995. Phytoremediation: a novel strategy for the removal of toxic metals from the environment using plants. Jour. Biotechnology. 13: 468–474.
Santillan, L. F. J., Constantino, C. A. L., Rodriguez., G. A. V., Ubilla, N. M. C., and Hernandez, R. I. B., 2010. Manganese accumulation in plants of the mining zone of Hidalgo, Mexico. Biores. Tech. 101 (15): 5836-5841.
Stoltz, E, and Greger, M., 2002. Accumulation properties of As, Cd, Cu, Pb and Zn by four wetland plant species growing on submerged mine tailings. Jour. Envir. Exp. Botany. 47: 271-280.
Thomas, G. W., 1996. Soil pH and soil acidity. P 475-490. In: Sparks et al. (eds.) Methods of soil analysis, part 3. Agron. Mongr. 9. 2nd ed. ASA and SSSA, Madison, WI.
U. S. EPA. 1993. Cleaning up the nation's waste sites; Market and Technology trends, office of solid waste and Emergency Response, Technology Innovation office, Washington Dc, EPA, 542-R-92-012.
Usman, A. R. A., Lee, S. S. L., Awad, Y. M., Lim, K. J., Yang, J. E., and Ok, Y. S., 2012. Soil pollution assessment and identification of hyperaccumulating plants in chromated copper arsenate CCA contaminated sites, Korea. Jour. Chemosphere. 872-878.
Usman, A. R. A, and Mohamed, H. M., 2009. Effect of microbial inoculation and EDTA on the uptake and translocation of heavy metal by corn and sunflower. Jour. Chemosphere. 76: 893–899.
Walkley, A, and Black, I. A., 1934. Review Examination of the Degtjareff method determining soil organic matter and a proposed modification of the chromic acid titration method. Soil Science, 34: 29-38.
Wang, A., Chunling, L., Renxiu., Y., Yahua, C., Zhenguo, S.,and Xiangdong, L., 2012. Metal leaching along soil profiles after the EDDS application-A field study. Jour. Envir. Pollution. 164: 204-210.
Wilkins, D. A., 1978. The measurement of tolerance to edaphic factors by means of root growth. New Phyto. 8: 623-633.
Wong, M. H., 2003. Ecological restoration of mine degraded soils, with emphasis on metal contaminated soils. Jour. Chemosphere, 50(6): 775–780.
Yang, J. E., Lee, W. Y., Ok, Y.S., and Skousen, J., 2009. Soil nutrient bioavailability and nutrient content of pine trees (Pinus thunbergii) in areas impacted by acid deposition in Korea. Jour. Envir. Monit. Assess. 157: 43–50.
Yoon, J., Cao, X., Zhou, Q., and Ma, L. Q., 2006. Accumulation of Pb, Cu, and Zn in native plants growing on a contaminated Florida site. Jour. Sci. total envir. 368: 456–464.
Zayed, A., Gowthaman, S., and Terry, N.,1998. Phyto-accumulation of trace elements by wetland plants. I. Duckweed. Jour. Envir Quality. 27: 715–721.
