Processing technologies for gold-telluride ores

Jian Zhang; Yao Zhang; William Richmond; Hai-peng Wang

doi:10.1007/s12613-010-0101-6

International Journal of Minerals, Metallurgy, and Materials ›› 2010, Vol. 17 ›› Issue (1) : 1 -10. DOI: 10.1007/s12613-010-0101-6

Article

Processing technologies for gold-telluride ores

Author information +

History +

PDF

Abstract

Gold telluride ores are important gold refractory ores due to the presence of sulfides and other gangue materials. The classification and main physical properties of gold telluride ores were described, and possible treatment methods including flotation, leaching, and oxidation were reviewed. The results show that flotation procedures are much easier for gold tellurides compared to other refractory gold-bearing ores. For the conventional cyanide leaching process, pretreatment such as oxidation is required to achieve high gold recovery. Roasting is a relatively simple but not environment-friendly method; bio-oxidation technology seems to be more suitable for the oxidation of flotation concentrate. Other treatment methods involve cyanide leaching, thiourea leaching, ammoniacal thiosulfate leaching, carbon-in-pulp, and resin-in-pulp, all of which are less commonly utilized.

Keywords

gold-tellurides / flotation / leaching / oxidation

Cite this article

Download citation ▾

Jian Zhang, Yao Zhang, William Richmond, Hai-peng Wang. Processing technologies for gold-telluride ores. International Journal of Minerals, Metallurgy, and Materials, 2010, 17(1): 1-10 DOI:10.1007/s12613-010-0101-6

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Chryssoulis S.L., Cabri L.J. Significance of gold mineralogical balances in mineral processing. Trans. Inst. Min. Metall. C, 1990, 99, C1.

[2]	Korbel P., Novak M. The Complete Encyclopedia of Minerals Rocks Minerals and Gemstones, 1999 Lisse, Rebo International Press, 296.

[3]	I.R. Jackman and K. Sarbutt, The recovery of gold from a telluride concentrate, [in] Proceedings of Randol Gold Forum ′90, Colorado, 1990, p.55.

[4]	K.J. Henley, N.C. Clarke, and P. Sauter, Evidence for the refractiveness of gold-silver tellurides, [in] Proceedings of Randol Gold Forum ′95, Perth, 1995, p.141.

[5]	Lu Z., Lawson F. Metallurgical properties of gold, silver and gold-silver tellurides, 1994 New York, Science Press, 60.

[6]	S. Jayasekera, I.M. Ritchie, and J. Avraamides, Prospects for the direct leaching of gold tellurides—recent developments, [in] Proceedings of Australasian Institute of Mining and Metallurgy World Gold ′91, Parkville, 1991, p.181.

[7]	S. Jayasekera, I.M. Ritchie, and J. Avraamides, Electrochemical aspects of the leaching of gold telluride, [in] Proceedings of Randol Gold Forum ′88, Colorado, 1988, p.187.

[8]	Venkatachalam S. Hydrometallurgy, 1998 Mumbai, Narosa Publishing House, 8.

[9]	Bindi L., Cipriani C. Ordered distribution of Au and Ag in the crystal structure of muthmannite, AuAgTe₂, a rare telluride from Sacarîmb, Western Romania. Am. Miner., 2004, 89(10): 1505.

[10]	Climo M., Watling H. R., Van-Bronswijk W. Biooxidation as pre-treatment for a telluride-rich refractory gold concentrate. Miner. Eng., 2000, 13(12): 1219.

[11]	Brierley J.A. Rawlings D.E. Heap leaching of gold-bearing deposits: theory and operational description. Biomining: Theory, Microbes and Industrial Processes, 1997 Berlin, Springer, 103.

[12]	Miller P.C. Rawlings D.E. The design and operating practice of bacterial oxidation plant using moderate thermophiles. Biomining: Theory, Microbes and Industrial Processes, 1997 Berlin, Springer, 81.

[13]	J.T. Smith, Selective treatment of tellurides at gold mines of Kalgoorlie, [in]_Symposium on Selective Treatment of Tellurides 1962, Kalgoorlie, 1963, p.3.

[14]	Colbert P. Woodcock J.T. Gold ore treatment at Emperor Gold Mining Co. Ltd., Vatukoula, Fiji. Mining and Metallurgical Practices in Australasia, 1980 Melbourne, AIMM Press, 492.

[15]	Yan D.S., Hariyasa H. Selective flotation of pyrite and gold tellurides. Miner. Eng., 1997, 10(3): 327.

[16]	Bulatovic S.M. Flotation behavior of gold during processing of porphyry copper-gold ores and refractory gold bearing sulfides. Miner. Eng., 1997, 10(9): 895.

[17]	Dunne R. Flotation of gold and gold-bearing ores. Advances in Gold Ore Processing, Developments in Mineral Processing, 2005 Netherland, Elsevier, 309.

[18]	L.I. Smith, Telluride recovery and treatment at Great Boulder Gold Mines Ltd., [in] Symposium on Selective Treatment of Tellurides 1962, Kalgoorlie, 1963, p.14.

[19]	Ellis S. Internal KCGM Report, 1998 Kalgoorlie, KCGM, 1.

[20]	Pleysier R., Cashmore B., Klauber C. CSIRO Report: Leaching of Gold Telluride Concentrates from KCGM No. DMR-1821, 2002 Kalgoorlie, KCGM, 1.

[21]	I.R. Jackman and K. Sarbutt, The recovery of gold from a telluride concentrate, [in] Proceedings of Randol Gold Forum ′90, Colorado, 1990, p.55.

[22]	Johnston W.E. Tellurides: Problem or alibi?. Eng. Min. J., 1933, 134, 333.

[23]	Kelley K.D., Romberger S.B., Beaty D.W., et al. Geochemical and geochronological constraints on the genesis of Au-Te deposits at cripple creek, Colorado. Econ. Geol., 1998, 93, 981.

[24]	Deschenes G., Lastra R., Brown J.R., et al. Effect of lead nitrate on cyanidation of gold ores: progress on the study of the mechanisms. Miner. Eng., 2000, 13(12): 1263.

[25]	Deschenes G., Rousseau M., Tardif J., et al. Effect of the composition of some sulfide minerals on cyanidation and use of lead nitrate and oxygen to alleviate their impact. Hydrometallurgy, 1998, 50, 205.

[26]	G. Deschenes, Effect of the mineralogy of sulfide-bearing gold ores on the performance of cyanidation and its control variables, [in] Proceedings of the Annual Meeting of the Canadian Mineral Processors, Ottawa, 2001, p.325.

[27]	Deschenes G., Pratt A., Fulton M., Guo H. Kinetics and mechanism of leaching synthetic calaverite in cyanide solutions. Miner. Metall. Proc., 2006, 23(3): 133.

[28]	Deschenes G., McMullen J., Ellis S., et al. Investigation on the cyanide leaching optimization for the treatment of KCGM gold flotation concentrate—phase 1. Miner. Eng., 2005, 18(8): 832.

[29]	Li J., Miller J.D. A review of gold leaching in acid thiourea solutions. Miner. Process. Extr. Metall. Rev., 2006, 27, 177.

[30]	Örgül S., Atalay Reaction chemistry of gold leaching in thiourea solution for a Turkish gold ore. Hydrometallurgy, 2002, 67(1–3): 71.

[31]	Salinas S.A., Romero M.A.E., Gonzalez I. Electrochemical dissolution of calaverite (AuTe₂) in thiourea acidic solutions. J. Appl. Electrochem., 1998, 28(4): 417.

[32]	Ubaldini S., Fornari P., Massidda R., Abbruzzese C. An innovative thiourea gold leaching process. Hydrometallurgy, 1998, 48, 113.

[33]	Li J., Miller J.D. Reaction kinetics of gold dissolution in acid thiourea solution using ferric sulfate as oxidant. Hydrometallurgy, 2007, 89(3–4): 279.

[34]	Grosse A.C., Dicinoski G.W., Shaw M.J., Haddad P.R. Leaching and recovery of gold using ammoniacal thiosulfate leach liquors (a review). Hydrometallurgy, 2003, 69(1–3): 1.

[35]	Aylmore M.G. Treatment of a refractory gold-copper sulfide concentrate by copper ammoniacal thiosulfate leaching. Miner. Eng., 2001, 14(6): 615.

[36]	Aylmore M.G., Muir D.M. Thiosulfate leaching of gold—a review. Miner. Eng., 2001, 14(2): 135.

[37]	Abbruzzese C., Fornyari P., Massidda R., et al. Thiosulfate leaching for gold hydrometallurgy. Hydrometallurgy, 1995, 39, 265.

[38]	Kongolo K., Mwema M.D. The extractive metallurgy of gold. Hyperfine Interact., 1998, 111, 281.

[39]	Dicinoski G.W. Novel resins for the selective extraction of gold from copper rich ores. South Afr. J. Chem., 2000, 53(1): 33.

[40]	J.M.W. MacKenzie, M.J. Virnig, and M.W. Johns, Henkel Aurix(R) resin—an update, [in] Proceedings of Randol Gold Forum ′95, Perth, 1995, p.325.