Identyfikatory
DOI
Warianty tytułu
Języki publikacji
Abstrakty
Remobilization of heavy metals from the bottom liner system due to the seepage of acid mine drainage (AMD) is an important concern in the long-term management of tailing impoundment. Titration tests were carried out to evaluate the acid buffering capacity (ABC) of sewage sludge and to investigate its effect on the remobilization of heavy metals. Test results demonstrate that the ABC increases with solid/liquid ratio and anaerobic incubation time and it is mainly attributed to the abundant organic matters contained and increasing carbonate loads. The added heavy metals (Zn, Pb, and Cu) were well immobilized during the anaerobic incubation stage but were released out dramatically during the acidification especially when pH drops below 6.0 because of dissolution of carbonates and cation exchange of clay minerals. The calculated results, from a simplified model, indicate that high levels of remobilization of heavy metals are not expected during the typical management time because of the high ABC of compacted sewage sludge barrier. These results support that sewage sludge is a suitable bottom liner material for the management of AMD from tailings.
Czasopismo
Rocznik
Tom
Strony
62--72
Opis fizyczny
Bibliogr. 34 poz., rys., tab., wykr.
Twórcy
autor
- Lanzhou University, China, School of Civil Engineering and Mechanics
autor
- Lanzhou University, China, School of Civil Engineering and Mechanics
- Ministry of Education, China
autor
- Lanzhou University, China, School of Civil Engineering and Mechanics
Bibliografia
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- 2. Alloway, B.J. & Jackson, A.P. (1991). The behavior of heavy-metals in sewage sludge amended soils, Science of the Total Environment, 100, pp. 151–176.
- 3. Benner, S.G., Blowes, D.W. & Ptacek, C.J. (1997). A full-scale porous reactive wall for prevention of acid mine drainage, Ground Water Monitoring and Remediation, 17, pp. 99–107.
- 4. Bourg, A.C.M. & Loch, J.P.G. (1995). Mobilization of heavy metals as affected by pH and redox conditions: biogeodynamics of pollutants in soils and sediments, Springer Berlin: Heidelberg.
- 5. Bozkurt, S. & Moreno, L. (2000) Neretnieks I. Long-term processes in waste deposits, Science of the Total Environment, 250, pp. 101–121.
- 6. Calmano, W., Hong, J. & Förstner, U. (1993). Binding and mobilization of heavy metals in contaminated sediments affected by pH and redox potential, Water Science and Technology, 28, pp. 223–235.
- 7. Connell, W.E. & Patrick, W.H. (1968). Sulfate reduction in soil: effects of redox potential and pH, Science, 159, pp. 86–87.
- 8. Costa, M.C., Martins, M., Jesus, C. & Duarte, J.C. (2008). Treatment of acid mine drainage by sulphate-reducing bacteria using low cost matrices, Water Air and Soil Pollution, 189, pp. 149–162.
- 9. Coz, A., Andrés, A., Soriano, S. & Ángel, I. (2004). Environmental behaviour of stabilised foundry sludge, Journal of Hazardous Materials, 109, pp. 95–104.
- 10. Doye, I. & Duchesne, J. (2003). Neutralisation of acid mine drainage with alkaline industrial residues: laboratory investigation using batch-leaching tests, Applied Geochemistry, 18, pp. 1197–1213.
- 11. Gulec, S.B., Benson, C.H. & Edil, T.B. (2005). Effect of acidic mine drainage on the mechanical and hydraulic properties of three geosynthetics, Journal of Geotechnical and Geoenvironmental Engineering, pp. 937–951.
- 12. Johnson, D.B. & Hallberg, K.B. (2005). Acid mine drainage remediation options: a review, Science of the Total Environment, 338, pp. 3–14.
- 13. Jung, C.H., Matsuto, T., Tanaka, N. & Okada, T. (2004). Metal distribution in incineration residues of municipal solid waste (MSW) in Japan, Waste Management, 24, pp. 381–391.
- 14. Kamon, M., Zhang, H. & Katsumi, T. (2002). Redox effects on heavy metal attenuation in landfill clay liner, Journal of the Japanese Geotechnical Society Soils and Foundation, 42, pp. 115–126.
- 15. Lazzaretti-Ulmer, M.A. & Hanselmann, K.W. (1999). Seasonal variation of the microbially regulated buffering capacity at sediment-water interfaces in a freshwater lake, Aquatic Sciences, 61, pp. 59–74.
- 16. Lottermoser, B. (2010). Mine wastes: characterization, treatment and environmental impacts, Springer Science & Business Media: Berlin.
- 17. Manassero, M., Benson, C.H. & Bouazza, A. (2000). Solid waste containment systems, in: ISRM International Symposium, International Society for Rock Mechanics (Eds.). The Chemical Rubber Company Press: Boca Raton.
- 18. Moosbrugger, R.E., Wentzel, M.C. & Loewenthal, R.E. (l993). A 5pH point titration method to determine the carbonate and SCFA weak acid/bases in anaerobic systems, Water SA, 19, pp. 29–39.
- 19. Nason, P., Alakangas, L. & Ohlander, B. (2013). Using sewage sludge as a sealing layer to remediate sulphidic mine tailings: a pilot-scale experiment, Northern Sweden, Environmental Earth Sciences, 70, pp. 3093–3105.
- 20. O’Kelly, B.C. (2005). Consolidation properties of a dewatered municipal sewage sludge, Canadian Geotechnical Journal, 42, pp. 1350–1358.
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- 22. Rozada, F., Otero, M., Morán, A. & García, A.I. (2008). Adsorption of heavy metals onto sewage sludge-derived materials, Bioresource Technology, 99, pp. 6332–6338.
- 23. Saria, L., Shimaoka, T. & Miyawaki, K. (2006). Leaching of heavy metals in acid mine drainage, Waste Management and Research, 24, pp. 134–140.
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- 26. Tessier, A., Campbell, P.G.C. & Bisson, M. (1979). Sequential extraction procedure for the speciation of particulate trace metals, Analytical Chemistry, 51, pp. 844–851.
- 27. Tuttle, J.H., Dugan, P.R. & Randles, A.C.I. (1969). Microbial sulfate reduction and its potential utility as an acid mine water pollution abatement procedure, Applied Microbiology, 17, pp. 297–302.
- 28. Wang, B., Zhang, H., Fan, Z. & Ju, Y. (2010). Compacted sewage sludge as a barrier for tailing impoundment, Environmental Earth Sciences, 61, pp. 931–937.
- 29. Waybrant, K.R., Blowes, D.W. & Ptacek, C.J. (1998). Selection of reactive mixtures for use in permeable reactive walls for treatment of mine drainage, Environmental Science and Technology, 32, pp. 1972–1979.
- 30. Yeheyis, M.B., Shang, J.Q. & Yanful, E.K. (2009). Feasibility of using coal fly ash for mine waste containment, Journal of Environmental Engineering, 136, pp. 682–690.
- 31. Yong, R.N., Mohamed, A.M.O. & Warkentin, B.P. (1992). Principles of contaminant transport in soils. Montreal: Elsevier Science Publishers.
- 32. Zhang, H., Yang, B., Zhang, G. & Zhang, X. (2016). Sewage sludge as barrier material for heavy metals in waste landfill, Archives of Environmental Protection, 42, pp. 52–58.
- 33. Zhang, H., Zhang, Q., Yang, B. & Wang, J. (2014). Compacted sewage sludge as a barrier for tailings: the heavy metal speciation and total organic carbon content in the compacted sludge specimen, Plos One, 9, e100932.
- 34. Zhao, S. & Men, F. (2008). Nutrition and security analysis of sludge protein as animal feed additive, China Feed, 15, pp. 35–38.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-41939adf-70cd-4d21-a4a9-30576914ab9c