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Assessing the Presence of Heavy Metals in the Area of Glloogoc (Kosovo) by Using Mosses as a Bioindicator for Heavy Metals

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This study aimed at determining the level of pollution from heavy metals that are deposited from air in the area of Gllogoc. The main goal was to identify the emission sources of pollution by using mosses as bio indicators. In this study area, the mining of Fe-Ni (Industrial Ferronickel Complex) is believed to strongly influence the level of heavy metals. The mining and production activity of Fe-Ni affects the soil, water and air. As the air pollution (from liberated aerosols of Industrial Ferronickel Complex) and the deposition products of this pollution are harmful not only locally but also can pollute the environmental at extended distances, the use of mosses allows analyzing the content and origin of the pollution from heavy metals. ICP was used for the determination of heavy metals in moss samples. The use of Principal Component Analysis (PCA), dendograms and other statistical procedures, permitted to understand the source of the air pollution from heavy metals.
Rocznik
Strony
135--140
Opis fizyczny
Bibliogr. 28 poz., rys., tab.
Twórcy
  • Faculty of Agroecology and Agroenvironment, University of Peja "Haxhi Zeka" St. UÇK 30000, Pejë, Kosovo
autor
  • Faculty of Agroecology and Agroenvironment, University of Peja "Haxhi Zeka" St. UÇK 30000, Pejë, Kosovo
  • University of Pristina "Hasan Pristina", Faculty of Natural Sciences and Mathematics, Department of Chemistry, str. "Nëna Tereze" nr. 5, 10000, Pristina, Kosovo
Bibliografia
  • 1. Everitt B.S. and Dunn G., 1992. Applied multivariate data analysis (Oxford University Press, New York.
  • 2. Barandovski L, Stafilov T, Šajn R, Frontasyeva M.V, Bačeva K., 2013. Air pollution study in Macedonia using a moss biomonitoring technique, ICP-AES and AAS. Macedonian Journal of Chemistry and Chemical Engineering, Vol. 32, No. 1, pp. 89–107.
  • 3. Blagnytė R, Paliulis D., 2010. Research into Heavy Metals Pollution of Atmosphere Applying Moss as Bioindicator: a Literature Review. Environmental Research, Engineering and Management, No. 4–54, p. 26–33.
  • 4. Bradl H.B., 2005. Heavy Metals in the Environment. Interface science and technology – volume 6. University of Applied Sciences Trier Neubrucke, Germany. Elsevier academic press: Amsterdam – Boston – Heidelberg – London – New York – Oxford – Paris San Diego – San Francisco – Singapore – Sydney – Tokyo.
  • 5. Canbay H.S., Doğantürk M. 2017. Metals Determination by Microwave Digestion ICP-OES of Some Dietary Supplements and Diet Products in Turkey. Eurasian Journal of Analytical Chemistry ISSN: 1306–3057 2017 12(1):45–53 DOI 10.12973/ejac.2017.00143a.
  • 6. Ceburnis D., Ruhling A. and Kvietkus K., 1996. Extended study of atmospheric heavy metal deposition in Lithuania based on moss analysis.
  • 7. Cekova L.B., Frontasyeva S.S, Pavlov T., Stafilov E, Steinnes V, Urumov М., 2006. Air pollution studies in Macedonia using the moss biomonitoring technique, naa, aas, and gis technology. Intended for submission to: Environmental Monitoring and Assessment.
  • 8. Chakrabortty Sh, Paratkar T., 2006. Biomonitoring of Trace Element Air Pollution Using Mosses. Aerosol and Air Quality Research, Vol. 6, No.3, pp. 247–258.
  • 9. Chen J.P, Wang L.K, Wang M.H.S, Hung Y.T, Shammas N.K., 2017. Remediation of heavy metals in the environment. CRC Press Taylor & Francis Group 6000 Broken Sound Parkway NW, Suite 300 Boca Raton, FL 33487–2742.
  • 10. Ferenc S., Uher P., Spišiak J., Šimonová V., 2016. Chromiumand nickel-rich micas and associated minerals in listvenite from the Muránska Zdychava, Slovakia: products of hydrothermal metasomatic transformation of ultrabasic rock. Journal of Geosciences 61, 239–254.
  • 11. Fernandez J.A, Carballeira A., 2002. Biomonitoring metal deposition in Galicia (NW Spain) with mosses: factors affecting bioconcentration. Chemosphere 46–535–542.
  • 12. Harmens H., Mills G., Hayes F., Norris D., et al. 2013. Air Pollution and Vegetation. ICP Vegetation Program me Coordination Centre, Centre for Ecology and Hydrology, Environment Centre Wales, Denial Road, Bangor, Gwinnett, LL57 2UW, UK http://icpvegetation.ceh.ac.uk.
  • 13. Harmens H., Norris D. et al. 2008. Spatial and temporal trends in heavy metal accumulation in mosses in Europe 1990–2005. Programme Coordination Centre for the ICP Vegetation.
  • 14. Herpin U., Siewers U., Markert B., Rosolen V., Breulmann G., Bernoux M., 2004. Second German Heavy–metal Survey by Means of Mosses, and Comparison of the First and Second Approach in Germany and other European Countries. Second Germany Heavy-metal Survey.
  • 15. Khare K, 2012. Air Pollution – Monitoring, Modeling, Health and Control, p. cm. ISBN 978–953–51–0381–3.
  • 16. Lazo P., Bekteshi L., Shehu A, 2013. Active Moss Biomonitoring Technique for Atmospheric Deposition of Heavy Metals in Elbasan City, Albania. Fresenius Environmental Bulletin. Volume 22 – No 1a.
  • 17. Lucaciu A, Timofte L, Culicov O, Frontasyeva M.V, Oprea C, Man S.C, Mocanu R., Steinnes E., 2004. Atmospheric Deposition of Trace Elements in Romania Studied by the Moss Biomonitoring Technique. Journal of Atmospheric Chemistry 49: 533–548.
  • 18. Markert B.A, Breure A.M, Zechmeister H.G., 2003. Bioindicators & BiomonitorsPrinciples, Concepts and Applications. Trace Metals and other Contaminants in the Environment 6. Elsevier: Amsterdam – Boston – London – New York – Oxford – Paris San Diego – San Francisco – Singapore – Sydney – Tokyo.
  • 19. Mazzoni A.C., Lanzer R., Bordin J., Schäfer A., Wasum R., 2012. Mosses as indicators of atmospheric metal deposition in an industrial area of southern Brazil. Acta Botanica Brasilica 26(3): 553–558.
  • 20. Nickel S., Hertel A, Pesch R., Schroder W., Steinnes E., Uggerud H.Th., 2014. Modeling and mapping spatio-temporal trends of heavy metal accumulation in moss and natural surface soil monitored 1990–2010 throughout Norway by multivariate generalized linear models and geostatistics. Atmospheric Environment.
  • 21. Nriagu J.O. and Pacyna J.M. 2001. Quantitative assessment of worldwide contamination of air, water and soils by trace metals. National Water Researcher Institute, Box 5050, Burlington, Ontario L7R4A6, Canada. Norwegian Institute for Air Pollution Researcher, PO Box 64, N-2001Lillestrom, Norway.
  • 22. Otvos E, Pazmandi T, Tuba Z., 2003. First national survey of atmospheric heavy metal deposition in Hungary by the analysis of mosses. The Science of the Total Environment 309; 151–160.
  • 23. Steinnes E., 2005. Use of mosses as biomonitors of atmospheric deposition of trace elements. Department of Chemistry, Norwegian University of Science and Technology, Trondheim, Norway Abstract; XA0055146.
  • 24. Vasconcelos M.T.S.D, Tavares H.M.F., 1998. Atmospheric metal pollution Cr, Cu, Fe, Mn, Ni, Pb and Ž Zn in Oporto city derived from results for low-volume. Aerosol samplers and for the moss Sphagnum auriculatum bioindicator. The Science of the Total Environment 212 – 11 Ž-20.
  • 25. Vukojević V., Sabovljević M., Sabovljević A., Mihajlović N., Dražić G., Vučinić Z., 2010. Determination of Heavy Metal Deposition in the Country of Obrenovac (Serbia) Using Mosses as Bioindicators ii: Cadmium (Cd), Cobalt (Cd), and Chromium (Cr). Arch. Biol. Sci., Belgrade, 58 (2), 95–104.
  • 26. Walker K. and Robert T., 2003. Terrestrial pollution in the Pechora basin, north-eastern European Russia. PhD thesis, University of Nottingham.
  • 27. WHO 2007. Joint /Convention Task Force on the Health Aspects of Air Pollution. Health risks of heavy metals from long-range transboundary air pollution. Address requests about publications of the WHO Regional Office for Europe to: (http://www.euro.who.int/pubrequest).
  • 28. Huang Y. and Wu P., 2007. Statistical analysis and application of SAS. China Machine Press, Beijing.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d3625a70-892d-465e-a829-f40c3e34f614
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