A review of gold extraction using noncyanide lixiviants: Fundamentals, advancements, and challenges toward alkaline sulfur-containing leaching agents

Chun-bao Sun; Xiao-liang Zhang; Jue Kou; Yi Xing

doi:10.1007/s12613-019-1955-x

International Journal of Minerals, Metallurgy, and Materials ›› 2020, Vol. 27 ›› Issue (4) : 417 -431. DOI: 10.1007/s12613-019-1955-x

Invited Review

A review of gold extraction using noncyanide lixiviants: Fundamentals, advancements, and challenges toward alkaline sulfur-containing leaching agents

Chun-bao Sun ¹^,²
, Xiao-liang Zhang ¹^,^b
, Jue Kou ¹^,²
, Yi Xing ³^,^d

Author information +

History +

PDF

Abstract

Alkaline sulfur-containing lixiviants, including thiosulfate, polysulfides, and alkaline sulfide solutions, stand out as a promising class of alternatives to cyanide because of their low toxicity, high efficiency, and strong adaptability. In this paper, we summarized the research progress and remaining challenges in gold extraction using these noncyanide reagents. After a brief introduction to the preparation method, the transformation process of various sulfur-containing species in alkaline solutions was discussed. Thereafter, some insights into the mechanism of gold leaching in alkaline sulfur-containing solutions were presented from different aspects, including thermodynamics analysis, electrochemical dissolution, and leaching kinetics. Moreover, recent progress in in-situ generation of sulfur-containing anions from gold-bearing sulfide minerals was outlined as well. Gold passivation caused by sulfur species was discussed in particular because it is considered the greatest challenge facing sulfur-containing leaching systems. Alkaline sulfur-containing lixiviants are expected to serve as alternatives in industrial applications of gold extraction, particularly for refractory gold ores containing copper and carbonaceous matter.

Keywords

gold extraction / sulfur-containing lixiviants / degradation / in-situ generation / passivation

Cite this article

Download citation ▾

Chun-bao Sun, Xiao-liang Zhang, Jue Kou, Yi Xing. A review of gold extraction using noncyanide lixiviants: Fundamentals, advancements, and challenges toward alkaline sulfur-containing leaching agents. International Journal of Minerals, Metallurgy, and Materials, 2020, 27(4): 417-431 DOI:10.1007/s12613-019-1955-x

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]	Breuer PL, Dai X, Jeffrey MI. Leaching of gold and copper minerals in cyanide deficient copper solutions. Hydrometallurgy, 2005, 78, 156.

[2]	Ofori-Sarpong G, Osseo-Asare K. Preg-robbing of gold from cyanide and non-cyanide complexes: Effect of fungi pretreatment of carbonaceous matter. Int. J. Miner. Process., 2013, 119, 27.

[3]	La Brooy SR, Linge HG, Walker GS. Review of gold extraction from ores. Miner. Eng., 1994, 7, 1213.

[4]	Dai X, Simons A, Breuer P. A review of copper cyanide recovery technologies for the cyanidation of copper containing gold ores. Miner. Eng., 2012, 25, 1.

[5]	Johnson CA. The fate of cyanide in leach wastes at gold mines: An environmental perspective. Appl. Geochem., 2015, 57, 194.

[6]	Senanayake G. Gold leaching in non-cyanide lixiviant systems: Critical issues on fundamentals and applications. Miner. Eng., 2004, 17, 785.

[7]	Smolyaninov V, Shekhvatova G, Vainshtein M. Gold leaching by organic base polythionates: New nontoxic and secure technology. SpringerPlus, 2014, 3, 1.

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

[9]	Sousa R, Futuro A, Fiúza A, Vila MC, Dinis ML. Bromine leaching as an alternative method for gold dissolution. Miner. Eng., 2018, 118, 16.

[10]	Ahtiainen R, Lundström M. Cyanide-free gold leaching in exceptionally mild chloride solutions. J. Cleaner Prod., 2019, 234, 9.

[11]	Konyratbekova SS, Baikonurova A, Akcil A. Non-cyanide leaching processes in gold hydrometallurgy and iodine-iodide applications: A review. Miner. Process. Extr. Metall. Rev., 2015, 36, 198.

[12]	Perea CG, Restrepo OJ. Use of amino acids for gold dissolution. Hydrometallurgy, 2018, 177, 79.

[13]	Oraby EA, Eksteen JJ, Karrech A, Attar M. Gold extraction from paleochannel ores using an aerated alkaline glycine lixiviant for consideration in heap and in-situ leaching applications. Miner. Eng, 2019, 138, 112.

[14]	Wen QJ, Wu YF, Wang X, Zhuang ZY, Yu Y. Researches on preparation and properties of sodium polysulphide as gold leaching agent. Hdrometallurgy, 2017, 171, 77.

[15]	Ha VH, Lee JC, Jeong J, Hai HT, Jha MK. Thiosulfate leaching of gold from waste mobile phones. Hazard. Mater, 2010, 178, 1115.

[16]	Lampinen M, Laari A, Turunen I. Ammoniacal thiosulfate leaching of pressure oxidized sulfide gold concentrate with low reagent consumption. Hydrometallurgy, 2015, 151, 1.

[17]	Wang Q, Hu XZ, Zi FT, Yang P, Chen YL, Chen SL. Environmentally friendly extraction of gold from refractory concentrate using a copper-ethylenediamine-thiosulfate solution. J. Cleaner Prod, 2019, 214, 860.

[18]	White HA. The solubility of gold in thiosulfates and thiocyanates. S. Afr. J. Sci, 1905, 1, 211.

[19]	Berezowsky RMGS, Sefton VB. Recovery of gold and silver from oxidation leach residues by applied to ammoniacal thiosulfate leaching. The 108th AIME Annual Meeting, 1979 17.

[20]	Jeffrey MI, Breuer PL, Chu CK. The importance of controlling oxygen addition during the thiosulfate leaching of gold ores. Int. J. Miner. Process., 2003, 72, 323.

[21]	Hilson G, Monhemius AJ. Alternatives to cyanide in the gold mining industry: What prospects for the future?. J. Cleaner Prod., 2006, 14, 1158.

[22]	Molleman E, Dreisinger D. The treatment of copper-gold ores by ammonium thiosulfate leaching. Hydrometallurgy, 2002, 66, 1.

[23]	Xu B, Yang YB, Li Q, Jiang T, Liu SQ, Li GH. The development of an environmentally friendly leaching process of a high C, As and Sb bearing sulfide gold concentrate. Miner. Eng., 2016, 89, 138.

[24]	Wang J, Wang W, Dong KW, Fu Y, Xie F. Research on leaching of carbonaceous gold ore with copper-ammonia-thiosulfate solutions. Miner. Eng., 2019, 137, 232.

[25]	Fleming CA, McMullen J, Thomas KG, Wells JA. Recent advances in the development of an alternative to the cyanidation process: Thiosulfate leaching and resin in pulp. Min. Metall. Explor, 2003, 20, 1.

[26]	Muir DM, Aylmore MG. Thiosulfate as an alternative lixiviant to cyanide for gold ores. Dev. Miner. Process., 2005, 15, 541.

[27]	Helm M, Vaughan J, Staunton WP, Avraamides J. An investigation of the carbonaceous component of preg-robbing gold ores. World Gold Conference, 2009 139.

[28]	Choi Y, Baron JY, Wang Q, Langhans J, Kondos P. Thiosulfate processing-from lab curiosity to commercial application. Proceedings of the World Gold, 2013 45.

[29]	Muir DM, Aylmore MG. Thiosulphate as an alternative to cyanide for gold processing—Issues and impediments. Miner. Process. Extr. Metall, 2004, 113, 2.

[30]	Xu B, Kong WH, Li Q, Yang YB, Jiang T, Liu XL. A review of thiosulfate leaching of gold: Focus on thiosulfate consumption and gold recovery from pregnant solution. Metals, 2017, 7, 222.

[31]	Weissberg BC. Solubility of gold in hydrothermal alkaline sulphide solutions. Econ. Geol, 1970, 65, 551.

[32]	Hiskey JB, Atluri VP. Dissolution chemistry of gold and silver in different lixiviants. Miner. Process. Extr. Metall. Rev., 1988, 4, 95.

[33]	Anderson C, Dahlgren E, Huang HH, Mranda PJ, Stacey D, Jeffrey M, Chandra I. Fundamentals and applications of alkaline sulfide leaching and recovery of gold. CM Gold Symposium, 2005 145.

[34]	Sparrow GJ, Woodcock JT. Cyanide and other lixiviant leaching systems for gold with some practical applications. Miner. Process. Extr. Metall. Rev., 1995, 14, 193.

[35]	Zhu GC, Feng ZH, Chen JY. Leaching of gold from sulphide concentrates with thiosulphate/polysulphide produced by disproportionation of elemental sulphur in ammoniacal media. Hydrometallurgy, 1994 541.

[36]	Yang TZ, Chen XG, Bin WD, Chen QB, Lu YY. Gold leaching in sodium polysulfide solution. J. Cent. South Inst. Min. Metall, 1992, 23, 687.

[37]	Anderson CG, Twidwell LG. Antimony, arsenic, gold, mercury and tin separation, recovery, and fixation by alkaline sulfide hydrometallurgy. Proceedings of Hydrometallurgy 2008, Sixth International Symposium, 2008 348.

[38]	Anderson CG. The application and economics of industrial alkaline leaching of copper enargite concentrates. Proceedings of Copper Cobalt Africa, 2015 12.

[39]	Anderson CG, Twidwell LG. Hydrometallurgical processing of gold-bearing copper enargite concentrates. Can. Metall. Q., 2008, 47, 337.

[40]	Parada Torres FA. The Alkaline Sodium Sulphide Leaching of Enargite, 2011 87.

[41]	Lau N, Pluth MD. Reactive sulfur species (RSS): Persulfides, polysulfides, potential, and problems. Curr. Opin. Chem. Biol, 2019, 49, 1.

[42]	Rosén E, Tegman R. A preparative and X-ray powder diffraction study of the polysulfides Na₂S₂, Na₂S₄, and Na₂S₅. Acta Chem. Scand., 1971, 25, 3329.

[43]	Anderson CG, Nordwick SM. Pretreatment using alkaline sulfide leaching and nitrogen species catalyzed pressure oxidation on a refractory gold concentrate. EPD Congress, 1996 323.

[44]	Anderson CG. Alkaline sulfide recovery of gold utilizing nitrogen species catalyzed pressure leaching. Hydrometallurgy, 2003, 1, 75.

[45]	Yang BY, Lan XZ, Zhang J, Han AY. Lime-sulphur-synthetic-solution (LSSS)—A new nontoxic eagent for extraction of gold. Precious Met, 1997, 18, 58.

[46]	Fang ZH, Han BL. Leaching gold using oxidation products of elemental sulfur in Ca(OH)₂ solution under oxygen pressure. Chin. J. Process Eng., 2002, 2, 230.

[47]	Hojjatie MM, Lockhart CLF, Dimitriadis A, Van Cauwenbergh J, Van Dael R. Continuous Process for Preparation of Calcium Thiosulfate Liquid Solution, 2013

[48]	Zhou J, Lan XZ, Zhang QL. Preparation of sodium thiosulfate and sodium polysulfide mixture for gold leaching. Nonferrous Met. (Extr. Metall), 2008, 4, 26.

[49]	Zhao LC, Sun CB, Li SY, Gong DZ. Effects of lime sulphur synthetic solution on leaching characteristic of gold concentrates. Chin. J. Nonferrous Met, 2015, 25, 786.

[50]	Wu H, Feng YL, Li HR, Liao SD, Wang HJ. Basic theory and optimization of gold containing antimony concentrate leaching by alkaline sulfide. Physcochem Probl. Miner. Process., 2019, 55, 248.

[51]	Rule A, Thomas JS. XXIII.—The polysulphides of the alkali metals. Part I. The polysulphides of sodium. J. Chem. Soc. Trans., 1914, 105, 177.

[52]	Kamyshny A, Golfman A, Gun J, Rizkov D, Lev O. Equilibrium distribution of polysulfide ions in aqueous solutions at 25°C: A new approach for the study of polysulfides’ equilibria. Environ. Sci. Technol., 2004, 38, 6633.

[53]	Filpponen I, Guerra A, Hai A, Lucia LA, Argyropoulos DS. Spectral monitoring of the formation and degradation of polysulfide ions in alkaline conditions. Ind. Eng. Chem. Res., 2006, 45, 7388.

[54]	Giggenbach WF. Equilibria involving polysulfide ions in aqueous sulfide solutions up to 240°C. Inorg. Chem., 1974, 13, 1724.

[55]	Licht S, Davis J. Disproportionation of aqueous sulfur and sulfide: Kinetics of polysulfide decomposition. J. Phys. Chem. B, 1997, 101, 2540.

[56]	Argyropoulos DS, Hou YH, Ganesaratnam R, Harpp DN, Koda K. Quantitative 1H NMR analysis of alkaline polysulfide solutions. Hozfoschung, 2005, 59, 124.

[57]	Kleinjan WE, Keizer A d, Janssen AJH. Kinetics of the chemical oxidation of polysulfide anions in aqueous solution. Water Res., 2005, 39, 4093.

[58]	Dhawale SW. Thiosufate: An interesting sulfur oxoanion that is useful in both medicine and industry-but is implicated in corrosion. J. Chem. Educ, 1993, 70, 12.

[59]	Aylmore MG, Muir DM. Thiosulfate leaching of gold—A review. Miner. Eng., 2001, 14, 135.

[60]	Pryor WA. The kinetics of disproportionation of sodium thiosulfate to sodium sulfide and sulfate. J. Am. Chem. Soc, 1960, 82, 4794.

[61]	Xu XB, Chang SG. Study of the disproportionation of sodium thiosulfate by x-ray photoelectron spectroscopy. Modern High Temperature Science, 1984 165.

[62]	Breuer PL, Jeffery MI. The reduction of copper(II) and the oxidation of thiosulfate and oxysulfur anions in gold leaching solutions. Hydrometallurgy, 2003, 70, 163.

[63]	Senanayake G. The role of ligands and oxidants in thiosulfate leaching of gold. Gold Bull, 2005, 38, 170.

[64]	Sitando O, Senanayake G, Dai X, Nikoloski AN, Breuer P. A review of factors affecting gold leaching in non-ammoniacal thiosulfate solutions including degradation and, in-situ generation of thiosulfate. Hydromeallurgy, 2018, 178, 151.

[65]	Zhang HG, Jeffrey MI. A kinetic study of rearrangement and degradation reactions of tetrathionate and trithionate in near-neutral solutions. Inorg. Chem., 2010, 49, 10273.

[66]	Varga D, Horváth AK. Kinetics and mechanism of the decomposition of tetrathionate ion in alkaline medium. Inorg. Chem., 2007, 46, 7654.

[67]	Zhang HG, Dreisinger DB. The kinetics for the decomposition of tetrathionate in alkaline solutions. Hydrometallurgy, 2002, 66, 59.

[68]	Choi Y, Kondos P, Aylmore MG, Mcmullen J, Van Weert G. Thiosulfate Generation in Situ in Precious Metal Recovery, 2009

[69]	Ji J, Fleming CA, West-Sells PG, Hackl RP. A novel thiosulphate system for leaching gold without the use of copper and ammonia. Hydrometallurgy 2003: 5th International Symposium Honoring Professor Ian M. Ritchie, 2003 227.

[70]	Pan CW, Liu Y, Horváth AK, Wang Z, Hu Y, Ji C, Zhao YM, Gao QY. Kinetics and mechanism of the alkaline decomposition of hexathionate ion. J. Phys. Chem. A, 2013, 117, 2924.

[71]	Zia Y, Mohammadnejad S, Abdollahy M. Gold passivation by sulfur species: A molecular picture. Miner. Eng., 2019, 134, 215.

[72]	Jeffrey MI, Anderson CG. A fundamental study of the alkaline sulfide leaching of gold. Eur. J. Miner. Process. Environ. Prot, 2003, 3, 336.

[73]	Anderson CG. Alkaline sulfide gold leaching kinetics. Miner. Eng., 2016, 92, 248.

[74]	Pourbaix M. Atlas of Electrochemical Equilibria in Aqueous Solutions, 1974

[75]	Aylmore MG, Muir DM. Thermodynamic analysis of gold leaching by ammoniacal thiosulfate using Eh/pH and speciation diagrams. Min. Metall. Explor, 2001, 18, 221.

[76]	A. Birich, S. Stopic, and B. Friedrich, Kinetic investigation and dissolution behavior of cyanide alternative gold leaching reagents, Sci. Rep., 9(2019), art. No. 7191.

[77]	Senanayake G. Analysis of reaction kinetics, speciation and mechanism of gold leaching and thiosulfate oxidation by ammoniacal copper(II) solutions. Hydomeallurgy, 2004, 75, 55.

[78]	Zhang SC. Oxidation of Refractory Gold Concentrates and Simultaneous Dissolution of Gold in Aerated Alkaline Solutions, 2004 228.

[79]	Yang YB, Gao W, Xu B, Li Q, Jiang T. Study on oxygen pressure thiosulfate leaching of gold without the catalysis of copper and ammonia. Hyrometallurgy, 2019, 187, 71.

[80]	Yu NW, Zhang J. The electrochemical study of leaching gold by LSSS method. Gold, 1998, 19, 34.

[81]	Parker GK, Watling KM, Hope GA, Woods R. A SERS spectroelectrochemical investigation of the interaction of sulfide species with gold surfaces. Colloids Surf., A, 2008, 318, 151.

[82]	Zhou H, Song YS, Li WJ, Song K. Electrochemical behavior of gold and its associated minerals in alkaline thiourea solutions. Int. J. Miner. Metall. Mater, 2018, 25, 737.

[83]	Kenzhaliyev BK, Dosymbaeva ZD, Iskhakova RR, Suleimenov EN. Investigation into the use of electrochemical extraction to draw gold from refractory ores. Am. J. Appl. Sci., 2015, 12, 857.

[84]	Martens E, Prommer H, Dai XW, Wu MZ, Sun J, Breuer P, Fourie A. Feasibility of electrokinetic in situ leaching of gold. Hydrometallurgy, 2018, 175, 70.

[85]	Nadirov RK, Syzdykova LI, Zhussupova AK. Electrochemical recovery of gold from concentrate by using sulfur-graphite electrode as the leaching agent source. J. Chem. Technol. Metall, 2018, 53, 556.

[86]	Breuer PL, Jeffrey MI. An electrochemical study of gold leaching in thiosulfate solutions containing copper and ammonia. Hydromeallurgy, 2002, 65, 145.

[87]	Zhang SC, Nicol MJ. An electrochemical study of the dissolution of gold in thiosulfate solutions. Part II. Effect of Copper. J. Appl. Electrochem., 2005, 35, 339.

[88]	Zhang SC, Nicol MJ. An electrochemical study of the dissolution of gold in thiosulfate solutions Part I: Alkaline solutions. J. Appl. Electrochem., 2003, 33, 767.

[89]	Oraby EA, Browner RE, Nikraz HR. Effect of silver in thiosulfate leaching of gold-silver alloys in the presence of copper and ammonia relative to pure gold and silver. Miner. Process. Extr. Metall. Rev., 2014, 35, 136.

[90]	Senanayake G. Gold leaching by thiosulphate solutions: A critical review on copper(II)-thiosulphate-oxygen interactions. Miner. Eng., 2005, 18, 995.

[91]	Zhang XM, Senanayake G. A review of ammoniacal thiosulfate leaching of gold: An update useful for further research in non-cyanide gold lixiviants. Miner. Process. Extr. Metall. Rev., 2016, 37, 385.

[92]	Jeffrey MI, Zheng J, Ritchie IM. The development of a rotating electrochemical quartz crystal microbalance for the study of leaching and deposition of metals. Meas. Sci. Technol., 2000, 11, 560.

[93]	Joshi S, Asselin E. Kinetics of gold leaching in alkaline sulfide solutions. Proceedings of the 50th Annual Conference of Metallurgists of CM, 2011 341.

[94]	Breuer PL, Jeffrey MI. Thiosulfate leaching kinetics of gold in the presence of copper and ammonia. Miner. Eng, 2000, 13, 1071.

[95]	Jeffrey MI. Kinetic aspects of gold and silver leaching in ammonia-thiosulfate solutions. rometallurgy, 2001, 60, 7.

[96]	Zelinsky AG, Novgorodtseva ON. EQCM study of the dissolution of gold in thiosulfate solutions. Hydrometallurgy, 2013, 138, 79.

[97]	Porvali A, Rintala L, Aromaa J, Kaartinen T, Forsen O, Lundstrom M. Thiosulfate-copper-ammonia leaching of pure gold and pressure oxidized concentrate. Physicochem. Probl. Miner. Process., 2017, 53, 1079.

[98]	Oraby ESA, Jeffrey MI. An electrochemical study of the dissolution of pure gold and gold-silver alloys in thiosulfate leach solutions. ECS Trans., 2010, 28, 237.

[99]	Sitando O, Dai X, Senanayake G, Nikoloski AN. Gold dissolution in non-ammoniacal thiosulphate soutions: Comparison of fundamentals and leaching studies. World Gold Conference 2015, 2015 1.

[100]

Chandra AP, Gerson AR. The mechanisms of pyrite oxidation and leaching: A fundamental perspective. Surf. Sci. Rep., 2010, 65, 293.

[101]

Huai YY, Plackowski C, Peng YJ. The surface properties of pyrite coupled with gold in the presence of oxygen. Miner. Eng, 2017, 111, 131.

[102]

Wang HP. A review on process-related characteristics of pyrrhotite. Miner. Process. Extr. Metall. Rev., 2008, 29, 1.

[103]

Fang ZH, Li ZJ, Shi W, Han BL. Gold leaching of a residue containing elemental sulfur with lime added under pressurized oxygen. Chin. J. Process Eng, 2002, 2, 17.

[104]

Melashvili M, Fleming C, Dymov I, Matthews D, Dreisinger D. Dissolution of gold during pyrite oxidation reaction. Miner. Eng, 2016, 87, 2.

[105]

Melashvili M, Fleming C, Dymov I, Matthews D, Dreisinger D. Equation for thiosulphate yield during pyrite oxidation. Miner. Eng, 2015, 74, 105.

[106]

Xu B, Li K, Zhong Q, Li Q, Yang YB, Jiang T. Study on the oxygen pressure alkaline leaching of gold with generated thiosulfate from sulfur oxidation. Hydrometallurgy, 2018, 177, 178.

[107]

Zhang XL, Sun CB, Xing Y, Kou J, Su M. Thermal decomposition behavior of pyrite in a mcrowave field and feasibility of gold leaching with generated elemental sulfur from the decomposition of gold-bearing sulfides. Hydrometallurgy, 2018, 180, 210.

[108]

Benzaazoua M, Marion P, Robaut F, Pinto A. Gold-bearing arsenopyrite and pyrite in refractory ores: Analytical refinements and new understanding of gold mineralogy. Mineral. Mag, 2007, 71, 123.

[109]

Zhang SH, Zheng YJ, Cao P, Li CH, Lai SZ, Wang XJ. Process mineralogy characteristics of acid leaching residue produced in low-temperature roasting-acid leaching pretreatment process of refractory gold concentrates. Int. J. Miner. Metall. Mater, 2018, 25, 1132.

[110]

Dai X, Jeffrey MI. The effect of sulfide minerals on the leaching of gold in aerated cyanide solutions. Hydrometallurgy, 2006, 82, 118.

[111]

Xu B, Yang YB, Li Q, Jiang T, Zhang X, Li GH. Effect of common associated sulfide minerals on thiosulfate leaching of gold and the role of humic acid additive. Hydrometallurgy, 2017, 171, 44.

[112]

Bas AD, Ghali E, Choi Y. A review on electrochemical dissolution and passivation of gold during cyanidation in presence of sulphides and oxides. Hydrometallurgy, 2017, 172, 30.

[113]

Kim R, Ghahreman A. The effect of ore mineralogy on the electrochemical gold dissolution behavior in various cyanide and oxygen concentrations. Effect of sulfidic ores containing heavy metals, Hydrometallurgy, 2019, 184, 75.

[114]

Jeffrey MI, Breuer PL. The cyanide leaching of gold in solutions containing sulfide. Miner. Eng., 2000, 13, 1097.

[115]

Azizi A, Petre CF, Olsen C, Larachi F. Electrochemical behavior of gold cyanidation in the presence of a sulfide-rich industrial ore versus its major constitutive sulfide minerals. Hydrometallurgy, 2010, 101, 108.

[116]

Briceno A, Chander S. Oxidation of hydrosulphide ions on gold Part I: A cyclic voltammetry study. J. Appl. Electrochem., 1990, 20, 506.

[117]

Woods R, Constable DC, Hamilton IC. A rotating ring disc electrode study of the oxidation of sulfur(-II) species on gold and sulfide minerals. Int. J. Miner. Process., 1989, 27, 309.

[118]

Hamilton IC, Woods R. An investigation of the deposition and reactions of sulphur on gold electrodes. J. Appl. Electrochem., 1983, 13, 783.

[119]

Wierse DG, Lohrengel MM, Schultze JW. Electrochemical properties of sulfur adsorbed on gold electrodes. J. Electroanal. Chem. Interfacial Electrochem., 1978, 92, 121.

[120]

Zelinsky AG. RDE study of thiosulfate oxidation on gold. J. Electroanal. Chem., 2014, 735, 111.

[121]

Bagdasaryan KA, Episkoposyan ML, Ter-Arakelyan KA, Babayan GG. The kinetics of the dissolution of gold and silver in sodium thiosulfate solutions. Sov. J. Non-ferrous Met, 1983, 376, 64.

[122]

Ter-Arakelyan KA, Bagdasaryan KA, Oganyan AG, Mkrtchyan RT, Babayan GG. On technological expediency of sodium thiosulphate usage for gold extraction from raw material. Izv. V.U.Z. Tsvetn. Metall., 1984 72.

[123]

Chen JY, Deng T, Zhu GC, Zhao J. Leaching and recovery of gold in thiosulfate based system—A research summary at ICM. Trans. Indian Inst. Met, 1996, 49, 841.

[124]

Jeffrey MI, Watling K, Hope GA, Woods R. Identification of surface species that inhibit and passivate thiosulfate leaching of gold. Miner. Eng., 2008, 21, 443.

[125]

Pedraza AM, Villegas I, Freund PL, Chornik B. Electro-oxidation of thiosulphate ion on gold: Study by means of cyclic voltammetry and Auger electron spectroscopy. J. Electroanal. Chem. Interfacial Electrochem., 1988, 250, 443.

[126]

Baron JY, Mirza J, Nicol EA, Smith SR, Leitch JJ, Choi Y, Lipkowski J. SERS and electrochemical studies of the gold-electrolyte interface under thiosulfate based leaching conditions. Electrochim. Acta, 2013, 111, 390.

[127]

Watling KM, Hope GA, Jeffrey MI, Woods R. Surface products on gold leached in ammoniacal copper(II) thiosulfate solution. ECS Trans., 2006, 2, 121.

[128]

Watling KM. Spectroelectrochemical Studies of Surface Species in the Gold/Thiosulfate System, 2007 242.

[129]

Nicol EA, Baron JY, Mirza J, Leitch JJ, Choi Y, Lipkowski J. Surface enhanced Raman spectroscopy studies of the passive layer formation in gold leaching from thiosulfate solutions in the presence of cupricion. J. Solid State Electrochem., 2014, 18, 1469.

[130]

Nie YH, Yu Q, Hu XZ, Zi FT, Yu H. The effect of ammonia on the anodic process of gold in copper-free thiosulfate solution. J. Electrochem. Soc, 2016, 163, 123.

[131]

Smith SR, Leitch JJ, Zhou CQ, Mirza J, Li SB, Tian XD, Huang YF, Tian ZQ, Baron JY, Choi Y, Lipkowski J. Quantitative SHINERS analysis of temporal changes in the passive layer at a gold electrode surface in a thiosulfate solution. Anal. Chem., 2015, 87, 3791.

[132]

Mrza J, Smith SR, Baron JY, Choi Y, Lipkowski J. A SERS characterization of the stability of poly-thionates at the gold-electrolyte interface. Surf Sci, 2015, 631, 196.

[133]

Huergo MA, Giovanetti L, Moreno MS, Maier CM, Requejo FG, Salvarezza RC, Vericat C. New insight into the chemical nature of the plasmonic nanostructures synthesized by the reduction of Au(III) with sulfide species. Langmuir, 2017, 33, 6785.

[134]

Lustemberg PG, Vericat C, Benitez GA, Vela ME, Tognalli N, Fainstein A, Martiarena ML, Salvarezza RC. Spontaneously formed sulfur adlayers on gold in electrolyte solutions: Adsorbed sulfur or gold sulfide?. J. Phys. Chem. C, 2008, 112, 11394.

[135]

Woods R, Hope GA, Watling KM, Jeffrey MI. A spectroelectrochemical study of surface species formed in the gold/thiosulfate system. J. Electrochem. Soc, 2006, 153, 105.

[136]

Mikhlin Y, Likhatski M, Tomashevich Y, Romanchenko A, Erenburg S, Trubina S. XAS and XPS examination of the Au-S nanostructures produced via the reduction of aqueous gold(III) by sulfide ions. J. Electron. Spectrosc. Relat. Phenom., 2010, 177, 24.

[137]

Rodriguez JA, Dvorak J, Jirsak T, Liu G, Hrbek J, Aray Y, González C. Coverage effects and the nature of the metal-sulfur bond in S/Au (111): High-resolution photoemission and density-functional studies. J. Am. Chem. Soc, 2003, 125, 276.