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Effect of Neutralising Substances on Selected Properties of Soil Contaminated With Cobalt

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Because of the potential threat for development of plants, resulting from the occurrence of too high cobalt contents in soil environment, a study was undertaken aiming to determine the effect of increasing soil contamination with cobalt (0, 20, 40, 80, 160, 320 mg·kg-¹ of soil), following the application of neutralising substances (farmyard manure, loam, charcoal, zeolite and calcium oxide), on the soil pH, hydrolytic acidity, total exchangeable bases, cation exchange capacity and the base saturation. In the series without neutralising substances added, soil contamination with the highest doses of cobalt resulted in a decrease in pH, in the total exchangeable bases, in the cation exchange capacity, and in the base saturation, and in an increase in the soil hydrolytic acidity. Of the applied neutralising substances, farmyard manure and particular calcium oxide had the greatest effect on the analysed soil properties. The application of the substances resulted in an increase in the soil pH, in the base exchange capacity, in the cation exchange capacity and in the base saturation and also in a decrease in the soil hydrolytic acidity. The other substances had no, or a small, effect on the studied soil properties.
Rocznik
Strony
193--197
Opis fizyczny
Bibliogr. 27 poz., tab.
Twórcy
autor
  • Department of Environmental Chemistry, University of Warmia and Mazury in Olsztyn, 4 Łódzki Sq., 10-727 Olsztyn, Poland
  • Department of Environmental Chemistry, University of Warmia and Mazury in Olsztyn, 4 Łódzki Sq., 10-727 Olsztyn, Poland
Bibliografia
  • 1. Azeez J.O., Van-Averbeke W. 2012. Dynamics of soil pH and electrical conductivity with the application of three animal manures. Communications in Soil Science and Plant Analysis, 43(6), 865–874.
  • 2. Bezerra J.D., Santos-Amaral R., Santos-Junior J. A., Genezini F.A., Cezar-Menezes R.S., Oliviera I.A. 2014. Characterization of Heavy Metals in a Uranium Ore Region of the State of Pernambuco, Brazil. Bulletin of Environmental Contamination and Toxicology, 92, 270–273.
  • 3. Biswas S., Dey R., Mukherjee S., Banerjee P. C. 2013. Bioleaching of nickel and cobalt from lateritic chromite overburden using the culture filtrate of Aspergillus niger. Applied Biochemistry and Biotechnology, 170, 1547–1559.
  • 4. Chatterjee J., Chatterjee C. 2002. Amelioration of phytotoxicity of cobalt by high phosphorus and its withdrawal in tomato. Journal of Plant Nutrition, 25 (12), 2731–2743.
  • 5. Collins R.N., Kinsela A.S. 2011. Pedogenic factors and measurements of the plant uptake of cobalt. Plant and Soil 339, 499–512.
  • 6. Devi G., Goplal-Bhattacharyya L.B.M., Devi A. 2014. Trace metal composition of PM2,5, soil and Machilus bombycina leaves and the effects on Antheraea assama silk worm rearing in the oil field area of Northeastern India. Water Air and Soil Pollution, 225, 1884–1897.
  • 7. Edwards A.C., Cuull M., Sinclair A.H., Walker R.L., Watsun C.A. 2012. Elemental status (Cu, Mo, Co, B, S, Zn) of Scottish agricultural soils compared with a soil-based risk assessment. Soil Use and Management, 28, 167–176.
  • 8. Filcheva E. G., Tsadilas C. D. 2002. Influence of clinoptilolite and compost on soil properties. Communications in Soil Science and Plant Analysis, 33 (3/4), 595–607.
  • 9. Glisic I.P., Milosevic T.M., Glisic I.S., Milosevic N.T. 2009. The effect of natural zeolites and organic fertilisers on the characteristics of degraded soils and yield of crops grown in Western Serbia. Land Degradation and Development, 20, 33–40.
  • 10. Karuppanapandian T., Kim W. 2013. Cobalt induced oxidative stress causes growth inhibition associated with enhanced lipid peroxidation and activates antioxidant responses in Indian mustard (Brassica juncea L.) leaves. Acta Physiologiae Plantarum, 35, 2429–2443.
  • 11. Kierczak J., Neel C., Aleksander-Kwaterczak U., Helios-Rybicka E., Bril H., Puziewicz J. 2008. Solid speciation and mobility of potentially toxic elements from natural and contaminated soils: A combined approach, Chemosphere, 73(5), 776–784.
  • 12. Kosiorek M., Wyszkowski M. 2016. Selected properties of cobalt-contaminated soil following the application of neutralising substances, Environmental Protection and Natural Resources, 27, 1(67), 22–25.
  • 13. Kukier U., Peters C.A., Chaney R.L., Angle J.S., Roseberg R.J. 2004. The effect of pH on metal accumulation in two Alyssum species. Journal of Environmental Quality, 33(6), 2090–2102.
  • 14. Lange B., Faucon M.P., Meerts P., Shutcha M., Mahy G., Pourret O. 2014. Prediction of the edaphic factors influence upon the copper and cobalt accumulation in two metallophytes using copper and cobalt speciation in soils. Plant and Soil, 379, 275–287.
  • 15. Li Z., Feng X., Bi X., Li G., Lin Y., Sun G. 2014. Probing the distribution and contamination levels of 10 trace metal/metalloids in soil near a Pb/Zn smelter in Middle China. Environmental Science and Pollution Research, 21, 4149–4162.
  • 16. Luo D., Zheng H., Chen Y., Wang G., Fenghua D. 2010. Transfer characteristics of cobalt from soil to crops in the suburban areas of Fujian Province, southeast China. Journal of Environmental Management, 91, 2248–2253.
  • 17. Micó C., Li H. F., Zhao F. J., Mcgrath S. P. 2008. Use of Co speciation and soil properties to explain variation in Co toxicity to root growth of barley (Hordeum vulgare L.) in different soils. Environmental Pollution, 156 (3), 883–890.
  • 18. Ostrowska A., Gawliński S., Szczubałka Z. 1991. Methods for analysis and evaluation of soil and plant properties. IOŚ Warszawa.
  • 19. Saaltink R., Griffioen J., Mol G., Birke M. 2014. Geogenic and agicultural controls on the geochemical composition of European agricultural soils. Journal of Soil and Sediments, 14, 121–137.
  • 20. Singh B., Bochereau F. J. M., Alloway B. J. 2000. Cadmium sorption behavior of natural and synthetic zeolites. Communications in Soil Science and Plant Analysis, 31 (17/18), 2775–2786.
  • 21. Wendling L.A., Kirbz J.K., Mclaughlin M.J. 2009. Aging effects on cobalt availability in soils. Environmental Toxicology and Chemistry, 28(8), 1609–1617.
  • 22. Werkenthin M., Kluge B., Wessolek G. 2014. Metals in European roadside soils and soil solution – A review. Environmental Pollution, 189, 98–110.
  • 23. Wyszkowski M., Modrzewska B. 2016. Acidity and sorption properties of zinc-contaminated soil following the application of neutralising substances. Journal of Ecological Engineering, 17(1), 63–68.
  • 24. Wyszkowski M., Sivitskaya V. 2015. Effect of different substances on some properties of soil contaminated with heating oil. Journal of Ecological Engineering, 16(1), 62–66.
  • 25. Wyszkowski M., Wyszkowska J. 2007. The content of macroelements in spring barley (Hordeum vulgare L.) and theirs relations with the enzymatic activity of cobalt contaminated soil. Proceeding of SECOTOX Conference and the International Conference on Environmental Management, Engineering, Planning and Economics, 1, 181–186.
  • 26. Wyszkowski M., Wyszkowska J. 2009. The effect of contamination with cadmium on spring barley (Hordeum vulgare L.) and its relationship with the enzymatic activity of soil. Fresenius Environmental Bulletin, 18(7), 1046–1053.
  • 27. Zupancic N., Skobe S. 2014. Antropogenic environment al impact in the Mediterranean coastal area of Koper/Capodistria, Slovenia. Journal of Soils and Sediments, 14, 67–77.
Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-588ff671-f155-4438-b56f-c08faae9fcdd
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