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A STUDY ON THE BIOOXIDATION OF AN ARSENICAL GOLD SULPHIDE CONCENTRATE WITH EXTREME THERMOPHILIC MICROORGANISMS
Abstract
Biooxidation of sulphide minerals has become an important method for the pretreatment of refractory gold ores. More over, bioleaching of the mi nerals with thermophilic microorganisms is attracting increasing interest as a promising alternative process. In this study, the biooxidation of an arsenical refractory gold sulphide concentrate using extreme thermophiles is examined. The concentrate contained 100.84 g/t Au, 31.8% pyrite (FeS2), 10.9% arsenopyrite (FeAsS), 0.2% chalcopyrite (CuFeS 2), 37.3% quartz (SiO2) and 19.8% gangue. Biooxidation experiments were conducted in Erlenmeyer flasks at 150 rpm and 68 oC. Highest sulphide oxidation with 60.8% over 432 h was achieved in the presence of the mixed culture, EXTM containing two strains ( Acidianus brierleyi and Sulfolobus metallicus). EXTM mixed culture was shown to biooxidize the concentrate more rapidly and extensively th an the pure cultures. Compared with the control test in the absence of microorgani sms, the dissolution of iron and arsenic was enhanced by 11.8–38.1% and 16.4–60.5% respectively in the presence of the archaeal strains. The increase in the pulp densit y was shown to adversely influence the biooxidation activity of the strains. After 24 h leaching time by direct cyanidation, low gold recovery was obtained (less than 20% Au). On the other hand, a high gold recovery was achieved for the biooxidized residues: after 24 h cyanidation gold dissolution reached about 77.1% Au.
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References23
Astudillo C. & Acevedo F. Adaptation of Sulfolobus metallicus to high pulp densities in the biooxidation of a flotation gold concentr ate, Hydrometallurgy, vol. 92, pp 11–15, 2008.
Olson G.J., Brierley J.A. & Brierley C.L. Appl. Microbiol. Biotechnol., vol. 63, pp 249–257, 2003.
Rawlings D.E., Tributsch H. & Hansford G.S. Microbiology, vol. 145, no. 1, pp 5– 13, 1999.
Melamud V.S., Pivovarova T.A., Kondrat’eva T.F. & Karavaiko G.I., Prikl. Biokhim. Mikrobiol., vol. 35, no. 2, pp 182–189, 1999.
Ladeishchikov V.V. Tekhnologiya izvlecheniya zolota i serebra iz upornykh rud (Technology of Gold and Silver Recovery from Resistant Ores), Irkutsk: Izd. OAO IRGIREDMET, vol. 1, 1999.
Vardanyan N.S. & Nagdalyan S.Z. Periodic Bioleaching of Refractory Gold- Bearing Pyrite Ore, Applied Biochemist ry and Microbiology, vol. 45, no. 4, pp 401–405, 2009.
Kargi F., Robinson J. Bi ological removal of pyritic sulfur from coal by the thermophilic organism Sulfolobus acidocaldarius, Biotechnol. Bioeng., vol. 23, pp 41–49, 1985.
Boogerd F., Van der Beemd C., Stoelwinder T., Bos P., Kuenen J. Relative contributions of biological and chemical reactions of the overall rate of pyrite oxidation at temperatures between 30 °C and 70 °C, Biotechnol. Bioeng., vol. 38, pp 109–115, 1991.
Kinnunen P.H.-M., Robertson W.J., Plum b J.J., Gibson J.A., Nichols P.D., Franzmann P.D., Puhakka J.A. The isola tion and use of iron oxidizing moderately thermophilic acidophiles from the Collie coal mine for the generation of ferric leaching solution, Appl. Microbiol. Biotechol., vol. 60, pp 748–753, 2003.
Tuffin I.M., De Groot P., Deane S.M., Rawlings D.E. An unusual Tn21-like transposon containing an ars operon is presen t in highly arsenic resistant strains of the biomining bacterium Acidithiobacillus caldus , J. Microbiology, vol. 151, pp 3027-3039, 2005.
Rawlings D.E. High level arsenic resistan ce in bacteria present in biooxidation tanks used to treat gold-bearing arsenopyrite concentrates: A review, Trans. Nonferrous Met. Soc. China, vol. 18, pp 1311-1318, 2008.
Chiu D. Chief Assayer, Inte rnational Plasma Labs (IPL) Limited, Fire/Wet Assay Department, www.ipl.ca, Canada, 2006.
APHA. American Public Health Asso ciation. Standard Methods for the Examination of Water and Wastewater, In: Clescerl, L.S., Greenberg, A.E., Eaton, A.D. (Eds.), American Water Works Association & Water Environment Federation, 20th ed.. ISBN: 0-87553-235-7. Washington, DC, 2000.
Norris P.R., Burton N.P., Foulis N.A.M. Acidophiles in bioreactor mineral processing, Extremophiles, vol. 4, pp 71-76, 2000.
Sandström A. & Petersson S. Bioleaching of a complex sulphide ore with moderate thermophilic and extreme thermophilic microorganisms, Hydromet allurgy, vol. 46, pp 181-190, 1997.
Deveci H. Effect of solids on viability of acidophilic bacteria, Minerals Engineering, vol. 15, pp 1181-1189, 2002.
Nemati M., Harrison S.T.L. & Hansford G.S. Biological oxidation of ferrous sulphate by Thiobacillus ferrooxidans : a review on kinetics aspects, Biochemical Engineering Journal, vol. 1, pp 171-190, 1998.
Nemati M. & Harrison S.T.L. Effect of solid loading on ther mophilic bioleaching of sulphide minerals, Journal of Chem ical Technology and Bi otechnology, vol. 75, no.7, pp 526-532, 2000.
Lindström E.B. & Gunneriusson L. Thermophilic bioleaching of arsenopyrite using Sulfolobus and a semi-continuous laboratory procedure, J. Indust. Microbiol., vol. 5, pp. 375-382, 1990.
Lindström E.B., Sandström A. & Sundkvist J.-E. A sequential two-step processes using moderately and extremely thermophilic cultures for biooxidation of refractory gold concentrates, Hydrometallurgy, vol. 71, pp 21-30, 2003.
Clark D.A. & Norris P.R. Oxidation of mineral sulphides by thermophilic microorganisms, Minerals Engineering, vol. 9, no. 11, pp 1119-1125, 1996.
Dew D.W. Comparison of performance for continuous bio-oxidation of refractory gold ore flotation concentrates. In: Biohydrom etallurgical Processing. (Jerez, C.A., Vargas, T., Toledo, H., Wiertz, J.V.,-eds.), vol. II, pp.239-251, University of Chile, Santiago, 1995.
Ciftci H. Biooxidation of refractory gold ore and concentrates, PhD Thesis, Suleyman Demirel University, Isparta, Turkey, 356 pp, 2008.
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