Evaluation of a sheep manure/limestone mixture for in situ acid mine drainage treatment

Environmental Engineering Science

Volumn 25, Issue 1, 2008, Pages 43-52

  Gibert, Oriol ^a   De Pablo, Joan ^a   Cortina, José Luis ^a,c   Ayora, Carlos ^b  

^a UNIVERSITAT POLITÈCNICA DE CATALUNYA   (Spain)

^b INSTITUTE OF EARTH SCIENCES JAUME ALMERA   (Spain)

^c Water Technology Centre ^*  (Spain)

Author keywords

Acid mine drainage; Biodegradability; In situ treatment; Metal toxicity; Sulphate reducing bacteria

Indexed keywords

BACTERIA; BIODEGRADABILITY; HEAVY METALS; LIMESTONE; SORPTION;

ACID MINE DRAINAGE; IN SITU TREATMENT; METAL TOXICITY; SULPHATE REDUCING BACTERIA;

MANURES;

HEAVY METAL; LIMESTONE; ORGANIC MATTER; SULFATE; ZINC;

ACID MINE DRAINAGE; ARTICLE; BACTERIAL METABOLISM; DISSOLUTION; EFFLUENT; HEAVY METAL REMOVAL; INFRARED SPECTROSCOPY; MANURE; MICROBIAL ACTIVITY; MICROBIAL DEGRADATION; PH; PRECIPITATION; SULFATE REDUCING BACTERIUM; WATER TREATMENT;

BACTERIA (MICROORGANISMS); OVIS ARIES;

EID: 38549151133     PISSN: 10928758     EISSN: None     Source Type: Journal    
DOI: 10.1089/ees.2006.0247     Document Type: Article

References (42)

1. APHA. (1992). Standard Methods for the Examination of Waste and Wastewater, Washington, DC: American Public Health Association,
2. BASU, O., and BALDWIN, S.A. (2000). Attachment and growth of sulphate-reducing bacteria on different support materials. Environ. Toxicol. 21, 1293.
3. BÉCHARD, G., YAMAZAKI, H., GOULD, W.D., and BÉDARD, P. (1994). Use of cellulosic substrates for the microbial treatment of acid mine drainage. J. Environ. Qual. 23, 111.
4. BENNER, S.G., BLOWES, D.W., PTACEK, C.J., and MAYER, K.U. (2002). Rates of sulfate reduction and metal sulfide precipitation in a permeable reactive barrier. Appl. Geochem. 17, 301.
5. rd International Conference on Groundwater Quality, Sheffield, p. 407.
6. CABRERA, G., PÉREZ, R., GÓMEZ, J.M., ÁBALOS, A., and CANTERO, D. (2006). Toxic effects of dissolved heavy metals on Desulfovibrio vulgaris and Desulfovibrio sp. strains. J. Hazard. Mater. A135, 40.
7. CHANG, I.S., SHIN, P.K., and KIM, B.H. (2000). Biological treatment of acid mine drainage under sulphate-reducing conditions with solid waste materials as substrate. Water Res. 34, 1269.
8. CHAPMAN, S.J., CAMPBELL, C.D., FRASER, A.R., and PURI, G. (2001). FTIR spectroscopy of peat in and bordering Scots pine woodland: Relationship with chemical and biological properties. Soil Biol. Biochem. 33, 1193.
9. CHEN, J.P., LIE, D., WANG, L., WU, S., and ZHANG, B. (2002). Dried waste activated sludge as biosorbents for metal removal: Adsorptive characterization and prevention of organic leaching. J. Chem. Technol. Biotechnol. 77, 657.
10. COCOS, I.A., ZAGURY, G.J., CLEMENT, B., and SAMSON, R. (2002). Multiple factor design for reactive mixture selection for use in reactive walls in mine drainage treatment. Water Res. 36, 167.
11. CORTINA, J.L., LAGRECA, I., DE PABLO, J., CAMA, J., and AYORA, C. (2003). Passive in situ remediation of metal-polluted water with caustic mgnesia: Evidence from column experiments. Environ. Sci. Technol. 37, 1971.
12. DE CARVALHO, R.P., GUEDES, K.J., PINHEIRO, M.V.B., and KRAMBROCK, K. (2001). Biosorption of copper by dried plant leaves studied by electron paramagnetic resonance and infrared spectroscopy. Hydrometallurgy 59, 407.
13. ELLIOTT, P., RAGUSA, S., and CATCHESIDE, D. (1998). Growth of sulfate-reducing bacteria under acidic conditions in an upflow anaerobic bioreactor as a treatment system for acid mine drainage. Water Res. 32, 3724.
14. GIBERT, O., DE PABLO, J., CORTINA, J.L., and AYORA, C. (2003). Evaluation of municipal compost/limestone/iron mixtures as filling material for permeable reactive barriers for in-situ acid mine drainage treatment. J. Chem. Technol. Biotechnol. 78, 489.
15. GIBERT, O., DE PABLO, J., CORTINA, J.L., and AYORA, C. (2004). Chemical characterisation of natural organic substrates as carbon sources for biological mitigation of acid mine drainage. Water Res. 38, 4186.
16. GIBERT, O., DE PABLO, J., CORTINA, J.L., and AYORA, C. (2005). Municipal compost-based mixture for acid mine drainage bioremediation: Metal retention mechanisms for permeable reactive barriers. Appl. Geochem. 20, 1648.
17. HAO, O.J. HUANG, L., CHEN, J.M., and BUGLASS, R.L. (1994). Effects of metal additions on sulphate reduction activity in wastewaters. Toxicol. Environ. Chem. 46, 197.
18. HARRIS, M.A., and RAGUSA, S. (2001). Bioremediation of acid mine drainage using decomposable plant material in a constant flow reactor. Environ. Geol. 40, 1192.
19. HAUG, R.T. (1993). The Practical Handbook of Compost Engineering. Boca Raton, FL: Lewis Publishers, by CRC Press LLC.
20. HERBERT, R.B., BENNER, S.G., PRATT, A.R., and BLOWES, D.W. (1998). Surface chemistry and morphology of poorly crystalline iron sulfides precipitated in media containing sulfate-reducing bacteria. Chem. Geol. 144, 87.
21. HSU, J.H., and LO, S.L. (1999). Chemical and spectroscopic analysis of organic matter transformations during composting of pig manure. Environ. Pollut. 104, 189.
22. JOHNSON, D.B., and HALLBERG, K.B. (2005). Biogeochemistry of the compost bioreactor components of a composite acid mine drainage passive remediation system. Sci. Total. Environ. 338, 81.
23. KIMURA, S., HALLBERG, K.B., and JOHNSON, D.B. (2006). Sulfidogenesis in low pH (3.8-4.2) media by a mixed population of acidophilic bacteria. Biodegradation 17, 159.
24. NECULITA, C.M., ZAGURY, G.J., and BUSSIÈRE, B. (2007). Passive treatment of acid mine drainage in bioreactors using sulphate-reducing bacteria: Critical review and research needs. J. Environ. Qual. 36, 1.
25. NUTTALL, C.A., and YOUNGER, P.L. (2000). Zn removal from hard, circum-neutral mine waters using a novel closed-bed limestone reactor. Water Res. 34, 1262.
26. PETHKAR, A.V., KULKARNI, S.K., and PAKNIKAR, K.M. (2001). Comparative studies on metal biosorption by two strains of Cladosporium cladosporioides. Bioresour. Technol. 80, 211.
27. st ed. Cambridge: Cambridge University Press.
28. PRASAD, D., WAI, M., BÉRUBÉ, P., and HENRY, J.G. (1999). Evaluating substrates in the biological treatment of acid mine drainage. Environ. Technol. 20, 449.
29. PUIGDOMÈNECH, I. (2001). Chemical Equilibrium Software Hydra and Medusa. Stockholm, Sweden: Inorganic Chemistry Department, Technology Institute.
30. RAHN, C.R., BENDING, G.D., LILLYWHITE, R.D., and TURNER, M.K. (1999). Chemical characterisation of vegetable and arable crop residue materials: A comparison of methods. J. Sci. Food Agric. 79, 715.
31. RAMOS, L., HERNÁNDEZ, L., and GONZÁLEZ, M.J. (1994). Sequential fractionation of copper, lead, cadmium and zinc in soils from or near Doñana National Park. J. Environ. Qual. 23, 50.
32. st ed. Madrid, Spain: Prentice Hall.
33. SHEORAN, A.S., and SHEROAN, V. (2006). Heavy metal removal mechanism of acid mine drainage in wetlands: A critical review. Miner. Eng. 19, 105.
34. TUTTLE, L.H., DUGAN, P.R., and RANDLES, C.I. (1969). Microbial sulfate reduction and its potential utility as an acid mine water pollution abatement procedure. Appl. Microbiol. 17, 297.
35. UTGIKAR, V.P., HARMON, S.M., CHAUDHARY, N., TABAK, H.H., GOVIND, R., and HAINES, J.R. (2002). Inhibition of sulphate-reducing bacteria by metal sulfide formation in bioremediation of acid mine drainage. Environ. Toxicol. 17, 40.
36. UTGIKAR, V.P, TABAK, H.H., HAINES, J.R., and GOVIND, R. (2003). Quantification of toxic and inhibitory impact of copper and zinc on mixed cultures of sulfate-reducing bacteria. Biotechnol. Bioeng. 82, 306.
37. WAYBRANT, K.R., BLOWES, D.W., and PTACEK, C.J. (1998). Selection of reactive mixtures for use in permeable reactive walls for treatment of mine drainage. Environ. Sci. Technol. 32, 1972.
38. WEI, X., VIADERO, R.C., and BUZBY, K.M. (2005). Recovery of iron and aluminum from acid mine drainage by selective precipitation. Environ. Eng. Sci. 22, 745.
39. WOULDS, C., and NGWENYA, B. (2004). Geochemical processes governing the performance of a constructed wetland treating acid mine drainage, Central Scotland. Appl. Geochem. 19, 1773.
40. WRIGHT, D.T., and WACEY, D. (2005). Precipitation of dolomite using sulphate-reducing bacteria from the Coorong Region, South Australia: Significance and implications. Sedimentology 52, 987.
41. YOUNGER, P.L., BANWART, S.A., and HEDIN, R.S. (2002). Minewater: Hydrology Pollution and Remediation. Dordrecht, The Netherlands: Kluwer Academic Publishers.
42. ZAGURY, G.J., KULNIEKS, V.I., and NECULITA, C.M. (2006). Characterization and reactivity assessment of organic substrates for sulphate-reducing bacteria in acid mine drainage treatment. Chemoshpere 64, 944.