A Review of Thiosulfate Leaching of Gold : Focus on Thiosulfate Consumption and Gold Recovery from Pregnant Solution

Thiosulfate leaching is a promising alternative to cyanidation, and the main hindrances for its wide commercial application are the high thiosulfate consumption and the difficult recovery of dissolved gold. In this review, the four solutions to reduce the consumption of thiosulfate, including the control of reaction conditions, the use of additives, the generation of thiosulfate in situ, and the replacement of traditional cupric-ammonia catalysis, are introduced and evaluated after the presentation of background knowledge about thiosulfate consumption. The replacement of cupric-ammonia catalysis with other metals, such as nickeland cobalt-based catalysts, is proposed. The reason is that it not only reduces thiosulfate consumption observably via decreasing the redox potential of leach solution significantly but also is beneficial to gold recovery mainly owing to eliminating the interference of cuprous thiosulfate [Cu(S2O3)3]. Based on the comparative analysis for five common recovery techniques of rare-noble metals from pregnant leach solution, ion-exchange resin adsorption is considered to be the most appropriate to recover aurothiosulfate [Au(S2O3)2] because the resin can be employed in the form of resin-in-leach/pulp and, furthermore, is able to be eluted and regenerated simultaneously at ambient temperature. At last, how to reduce the process cost of the resin adsorption technique is discussed. In order to simplify the complex two-stage elution process for loaded resins, the traditional catalysis is suggested to be replaced.


Introduction
Cyanidation has been the predominant gold leaching technique since it was first put forward by John Stewart MacArthur in the 1880s [1] because of its simple process and low cost.However, unluckily, cyanide is highly toxic, and there have been some serious environmental accidents occurring around the world caused by the leakage of cyanide from metallurgical plants [1][2][3].Due to of environmental concerns, cyanide leaching has been banned in many regions at present.Furthermore, the leaching period of cyanidation is usually as long as 24 h [3] and gold cannot be effectively leached from refractory gold ores.Thus, alternative lixiviants for gold have received more and more attention in recent years.Among those lixiviants, chloride, thiourea, and thiosulfate have received the most attention.The development of chloride leaching is impeded mainly by its hazardous working environment, poor reaction selectivity, and high requirements for equipment corrosion protection [4][5][6].The future of thiourea leaching is not attractive because the consumption and price of thiourea are both high and, furthermore, it is a suspected carcinogen [7][8][9][10].Thiosulfate leaching is widely considered to be the most promising alternative method owing to its reduced environmental risk, high reaction selectivity, low corrosivity of leach solution, cheap reagents, etc. [11][12][13][14][15].
Thiosulfate leaching was first proposed as a part of Von Patera process [16], where the leaching was implemented after chloridizing roasting.In the initial stage of thiosulfate leaching, high temperature and pressure were required until an improvement was carried out by using ammoniacal thiosulfate solution to leach copper-bearing sulfide ores at ambient temperature [17].From then on, the studies about cupric-ammonia catalyzed thiosulfate leaching at room temperature began to prevail.So far, there have been a large number of literature reported in this field on the effects of ore types and reaction conditions [16,[18][19][20].However, the successful commercial application of thiosulfate leaching is almost nonexistent, except that it is being used by Barrick Gold Corporation (Elko, NV, USA) in its Goldstrike deposit with the pretreatment of acidic or alkaline pressure oxidation [21][22][23].The carbonaceous gold ore in Goldstrike deposit cannot be efficiently leached by cyanidation due to the "preg-robbing" phenomenon, however, this phenomenon does not occur during thiosulfate leaching owing to the very weak affinity of carbonaceous substance for gold thiosulfate complex [24].This also leads to the problem that the dissolved gold in thiosulfate solution cannot be effectively recovered by active carbon adsorption which is the dominant technique used for pregnant cyanide solution.The dissolved gold in the Goldstrike deposit is recovered by a resin-in-leach process, and the loaded resin is eluted with a complex two-stage process.According to the literature [18,23], the thiosulfate consumptions in different studies are usually over 25 kg/t-ore during leaching and the dissolved gold cannot be effectively recovered by the simple techniques of active carbon adsorption and cementation that is used widely in cyanidation, both of which make the commercial competitiveness of thiosulfate leaching weak.Thus, the industrial application of this alternative method is still rare up to now.
In this review, the background knowledge about thiosulfate consumption will be presented at first, and then four solving measures to reduce the consumption are evaluated in detail.Afterwards, five common recovery techniques for rare-noble metals from leach solution are comparatively analyzed.In the end, how to improve the economy of the resin adsorption technique is discussed.The main intentions of this review are to propose an optimal approach for the reduction of thiosulfate consumption and a commercially-viable technique to recover dissolved gold from pregnant thiosulfate solution.

Background Knowledge about Thiosulfate Consumption
High thiosulfate consumption is one of bottlenecks for the wide industrialization of thiosulfate leaching.Yen et al. [25] thought thiosulfate leaching is not competitive compared with cyanidation unless the thiosulfate consumption is controlled below 10 kg/t-ore.However, as mentioned above, the consumption is usually higher than 25 kg/t-ore, and sometimes it even exceeds 100 kg/t-ore.For example, as reported in the literature [16], the thiosulfate consumption reached up to 165 kg/t-ore for a copper bearing gold ore.The main reasons for excessive thiosulfate consumption are as follows: thiosulfate itself is metastable and easily oxidized by Cu(II) and, furthermore, certain associated minerals can accelerate its oxidation [7,14].

Electrochemical-Catalytic Mechanism of Thiosulfate Leaching
The total reaction of thiosulfate leaching of pure gold is indicated in Equation (1), and the values of standard Gibbs free energy for Equations (1)-( 13) were all calculated based on the thermodynamic data in the literature [26].The essence of this reaction is an electrochemical process consisting of the oxidation of gold at the anode and reduction of oxygen at the cathode [27,28].In fact, the reaction is very sluggish without the presence of Cu(II) and ammonia, and the speed of gold leaching increases 18 to 20 times with their catalysts [29].The electrochemical-catalytic mechanism of thiosulfate leaching of gold foil is described in Figure 1.In anodic areas, NH 3 moves to the gold surface and complexes with Au + to generate the complex [Au(NH 3 ) 2 ] + .Then These cathodic reactions are listed as Equations ( 5) and ( 6).It is worth noting that [Cu(NH 3 ) 4 ] 2+ as a catalyzer boosts gold dissolution dramatically, but it also markedly accelerates thiosulfate decomposition due to its relatively strong oxidizing ability [27].As shown in Equation ( 7 2, and the corresponding reactions are listed as Equations ( 8)- (11).Equation ( 8) actually represents the total chemical reaction of Equations ( 6) and (7).According to the literature [31]

Effect of Associated Minerals
It is demonstrated that associated minerals, such as pyrite and hematite, can catalyze the decomposition of thiosulfate [35,36].By the comparison of four common sulfide minerals, Feng and Van Deventer [37] concluded that the catalytic effect of pyrite on thiosulfate decomposition is stronger than that of arsenopyrite, pyrrhotite, and chalcopyrite.Xu and Schoonen [38] attributed this effect of pyrite to its band structure.As Figure 4 shows, Chen [7] divided the oxidation of thiosulfate catalyzed by pyrite into several steps.At first, thiosulfate is absorbed onto pyrite surface due to its strong affinity for S 2 O 3 2− .After the adsorption, electrons move from thiosulfate to the surface, and then further transfer from the anodic area to the cathodic area via the conduction band of minerals.Finally, oxygen obtains electrons easily from the cathodic area of the mineral surface.In the presence of Cu(II)-ammine complex, it will preferentially gain an electron because its diffusibility in the solution is stronger than that of oxygen [35].It is easy to know from this figure that pyrite catalyzes thiosulfate oxidation by providing a "bridge" for electron transfer.In addition, Chen [7] also found that the presence of pyrite, pyrrhotite, chalcopyrite, arsenopyrite, chalcocite, bornite, and galena has significant detrimental effects on both of thiosulfate decomposition and gold leaching.Xu et al. [39] found that all studied sulfide minerals can accelerate thiosulfate consumption and hinder gold dissolution in different extent.The rates of thiosulfate consumption with the presence of sulfide minerals followed the descending order of pyrite > arsenopyrite > chalcopyrite > galena > sphalerite, and the rates of gold dissolution were in the sequence of sphalerite > arsenopyrite > pyrite ≈ galena > chalcopyrite.The dominant causes for these two detrimental effects of sulfide minerals were inferred separately via the analyses of frontier orbital energy and XPS (X-ray photoelectron spectroscopy) to be the catalyses of these minerals on thiosulfate decomposition and the passivation of gold surfaces [39].From the above, it is concluded that certain associated minerals can catalyze thiosulfate oxidation and, thus, accelerate the consumption.The minerals also hinder gold leaching because of the accumulation of passivation species deriving from thiosulfate decomposition on gold surfaces.

The Control of Reaction Conditions
Favorable reaction conditions are important to control thiosulfate consumption and promote gold dissolution [1].Although gold dissolution is evidently enhanced by a high Cu(II) concentration, the thiosulfate consumption deriving from its oxidation by Cu(II) also increases markedly.Yen et al. [40] put forward that high concentration ammonia reduces thiosulfate decomposition, but also hinders gold dissolution because it can stabilize Cu(II) and decrease its oxidizing ability.Concentrated thiosulfate solutions, excessive dissolved oxygen and high temperature all cause high consumption of thiosulfate, but diluted thiosulfate solutions, low oxygen concentration (for example, anaerobic condition) and low temperature make gold dissolution very slow [12,41,42].Additionally, reagent concentrations, solution pH should also be kept in an appropriate range.Molleman and Dreisinger [43] proposed that the pH range of 9-10 is preferred to simultaneously stabilize thiosulfate and copper ammonia complex.Moreover, the concentration ratio of Cu(II) to Cu(I) is also a critical factor for both of thiosulfate consumption and gold dissolution because the ratio determines the oxidation potential of leach solution [16,44].Oxygen plays an important role in changing the ratio by oxidizing Cu(I) to Cu(II).Furthermore, the concentration ratio of thiosulfate to ammonia should be maintained in a range of 0.5-1.0 in order to ensure the regeneration of Cu(II), because S 2 O 3 2− and NH 3 are separately the dominant ligands of Cu(I) and Cu(II) in ammoniacal thiosulfate solution [24,43].Most of above-mentioned reaction conditions are constantly changing during leaching, so it is very difficult to precisely control each of them.However, the adoption of relatively low reagent concentrations under limited oxygen supply is a relatively easy method to decrease thiosulfate consumption.Lampinen et al. [13] demonstrated that satisfactory gold dissolution from a pressure oxidized sulfide gold concentration and negligible thiosulfate consumption can be achieved with low concentrations of ammonia (0.2 M), thiosulfate (0.2 M) and Cu(II) (1.6 mM) under continuous aeration (0.2 L/min air).Based on the literature [12,24,36,45], the mixed pulp potential determined by the Cu(II)/Cu(I) redox equilibrium potential is a key factor for thiosulfate leaching, and there is a proper mixed potential range for both of high gold leaching ratio and acceptable thiosulfate consumption.
According to the above analysis, the concentrations of thiosulfate, ammonia, and dissolved oxygen all can greatly affect the ratio of Cu(II)/Cu(I) and, thus, significantly impact the mixed potential.Certain associated minerals also have obvious influence on the potential, because they will be evidently oxidized and largely consume Cu(II) in ammoniacal thiosulfate solution [39,46] and, moreover, the interfacial potential of mineral particles is also an important ingredient of the mixed potential of actual slurry [47].For each type of ore, the mixed pulp potential should be able to be adjusted into the appropriate range mainly by controlling the concentrations of thiosulfate, copper, ammonia, and dissolved oxygen.Thus, the regulation of mixed pulp potential will likely be an effective means to improve thiosulfate leaching.

Inorganic Additives
Some inorganic additives can be dedicated to reduce thiosulfate consumption.At the initial development stage, SO 3 2− and S 2− were added into thiosulfate solution [3].As shown in Equations ( 14)-( 16), SO 3 2− can reduce tetrathionate to thiosulfate in alkaline media, and trithionate and tetrathionate can also be reduced to thiosulfate by S 2− .However, the S 2− will precipitate dissolved gold and impede gold leaching.Certain additives can easily complex with the central cupric ion of Cu(II) and occupy its axial coordination site, thus the Cu(II) is stabilized significantly and the formation of mixed ligand complex Cu(NH 3 ) 4 S 2 O 3 is prevented.As a result of this, the oxidation of thiosulfate by Cu(II) gets restrained.Senanayake [31] concluded that the performances of anionic additives for the reduction of thiosulfate consumption are in the sequence of phosphate > sulfate > chloride > nitrate > sulfite > sulfide, because the coordinating abilities of these anions for cupric ions, i.e., their abilities to stabilize Cu(II), are exactly in this order based on the analysis of hard-soft and Lewis acid-base concept.Feng and Van Deventer [48] confirmed that hexametaphosphate and orthophosphate both can decrease thiosulfate consumption and enhance gold dissolution, and hexametaphosphate has a better effect because it not only stabilizes Cu(II) via complexing with the cupric ion at the axial coordination site, but also disperses leach slurry by improving its rheology.The influence of cations, including calcium, sodium, and ammonium, on the leaching of a pyrite concentrate has been studied by Feng and Van Deventer [49], and the results showed that calcium thiosulfate and sodium thiosulfate have the best effect on gold leaching and thiosulfate consumption, respectively.

Organic Macromolecular Additives
In recent decades, some organic macromolecular compounds have also been found to weaken the interaction between Cu(II) and thiosulfate and, thus, decrease thiosulfate consumption.As reported in the literature [36], a natural guar type surfactant (Gempolym M47) reduced the detrimental effect of hematite on thiosulfate consumption because it could stabilize Cu(II) and minimize the catalytic effect of hematite on thiosulfate decomposition.Ethylene diamine tetraacetic acid (EDTA) is a widely used complexing reagent, and can also complex with Cu(II) and forms a more stable coordination compound.Thus, the addition of EDTA decreases thiosulfate consumption [50].In addition to the coordination with Cu(II), carboxymethyl cellulose (CMC) changes the semiconductor characteristic of arsenopyrite surfaces and, thus, relieves the negative impact of arsenopyrite on thiosulfate decomposition [11].Commercially-available amino acids, such as L-valine, glycine, DL-α-alanine, and L-histidine, can also reduce thiosulfate consumption [51].Ammonium alcohol polyvinyl phosphate does not only decrease the consumption, but also markedly enhances gold leaching because the electronegative long-chain alcohol polyvinyl significantly improves the rheology of leach slurry [52].
Humic acid (HA) is a mixture of macromolecular organics and can be easily extracted from peat, lignite and decomposed coal, whose molecules have abundant negatively-charged functional groups like carboxyl and hydroxyl groups [53].The gold extraction from a refractory gold concentrate calcine was improved from 72.6% to 81.4% and thiosulfate consumption was reduced from 42.7% to 13.2% by the use of HA [54].Compared with other additives, such as CMC, CMS (sodium carboxymethyl starch), NaCl, and Na 2 SO 3 , HA had the best performance on the decrease of consumption and improvement of gold leaching.Xu et al. [39] further studied the role of HA on thiosulfate leaching in the presence of common associated sulfide minerals, and the results indicated that the HA effectively reduced the harmful effect of sulfide minerals.The acting mechanism of HA was studied in detail, mainly through the analyses of mixed pulp potential, zeta potential, and XPS, and was proposed as follows: humic acid radical ions not only weaken the interaction between Cu(II) and thiosulfate via complexing with the central cupric ion at its axial coordination site and relieve the catalytic effect of minerals on thiosulfate decomposition by making the affinity of mineral surfaces for S 2 O 3 2− disappear, but also prevent passivation species from coating gold surfaces through electrostatic repulsion.

The Generation of Thiosulfate In Situ
Thiosulfate can be generated by the oxidation of elemental sulfur in alkaline media, and the generated thiosulfate is able to efficiently leach gold.For example, the S 0 in an acid leaching residue was oxidized into thiosulfate during alkaline pressure oxidation under the condition of 85 • C, P O 2 0.1-0.3MPa and n(OH − /S 0 ) 0.90-1.25,and 90% of gold in the residue was simultaneously extracted by the formed thiosulfate [55].In another study, more than 80% of S 0 added at 0.8 M in lime milk solution in an autoclave was transformed into thiosulfate under 85 • C, P O 2 0.35 MPa and n(Ca/S 0 ) 0.55, and the gold extraction from an oxide gold ore containing negligible copper (0.007%, mass percent) by generated thiosulfate reached 81.6% after 5 h of leaching [56].This implies that gold can be efficiently leached at relatively high temperature and oxygen partial pressure without cupric-ammonia catalysis.Calcium thiosulfate can also be produced by the oxidation of S 0 in lime milk solution with a two-step process [57].At the first step, calcium polysulfide and calcium polythionate are formed by the reactions between the elemental sulfur, oxygen, and lime at 70-75 • C and P O 2 0.3-0.5 MPa, and at the second step these two products are both further converted into calcium thiosulfate at 80-95 • C and P O 2 0.3-0.5 MPa.The overall reaction for the generation of calcium thiosulfate is listed as Equation (17).The S 0 can be obtained via the oxidation of sulfidic gold-bearing feed during acidic pressure oxidation pretreatment, and then the obtained S 0 was further reacted with added sulfite to form thiosulfate.The gold occurring in sulfidic feed was efficiently leached by the formed thiosulfate [58].
Thiosulfate can also be directly generated by the oxidation of element S in sulfide minerals in alkaline media.Melashvili et al. [30] studied the equation for thiosulfate yield during pyrite oxidation, and found that the sulfur in pyrite can be directly oxidized into thiosulfate under the condition of 80 • C, P O 2 0.07-0.28MPa, and pH 12.5.As shown in Figure 5, the oxidation of sulfur in pyrite is a quasi-chain reaction process, where the valence of S is gradually increasing along the direction from left to right.Melashvili et al. [59] further investigated the simultaneous dissolution of gold by in situ formed thiosulfate during pyrite oxidation, and the best result was that 96% of gold and 75% of silver were leached from a pyrite concentrate whilst 60% of sulfide sulfur is oxidized.Xu et al. [60] found that the S in sulfidic gold-bearing ores/concentrates was partially oxidized into thiosulfate during alkaline pressure oxidation pretreatment under the condition of CaO 30-80 kg/t-feed, 140-160 • C and P O 2 0.3-0.4MPa, and a part of gold in the feed was leached by the generated thiosulfate.From the above, it is worth noting that the generations of thiosulfate from elemental sulfur or sulfide minerals are both under high temperature and oxygen concentration.Thus, the solution composition is very complex due to the decomposition of formed thiosulfate under the strong oxidizing environment, which is detrimental to the gold recovery by resin adsorption [18].

The Replacement of Traditional Cupric-Ammonia Catalysis
Traditional cupric-ammonia catalysis has three inherent drawbacks [18,20].The first one is that the thiosulfate decomposition is also catalyzed by Cu(II).The second one is the negative influence of copper on gold recovery from pregnant leach liquor.Copper ions are co-precipitated with dissolved gold during cementation using pulverized metal such as zinc and iron, and also are co-deposited on cathode surfaces during electrowinning.[Cu(S 2 O 3 ) 3 ] 5− that is the predominant form of Cu(I) in ammoniacal thiosulfate solution seriously interferes with the adsorption or extraction of [Au(S 2 O 3 ) 2 ] 3− by ion exchange resins or extractants due to the same ligand of these two coordination ions.The last one is that ammonia is poisonous and likely to pollute the atmosphere and water by volatilization and drainage.Thus, there have been some studies about the replacement of cupric-ammonia catalysis.
Fe 3+ was considered to replace Cu 2+ because it has also enough high potential to oxidize gold in ammoniacal thiosulfate solution, based on the thermodynamic knowledge that E 0 (Fe 3+ /Fe 2+ ) (0.77 V) is higher than E 0 (Cu 2+ /Cu + ) (0.15 V) [3].Oxalate and EDTA both can stabilize iron ions in alkaline media and, thus, were adopted to substitute ammonia [61,62].Although negligible thiosulfate consumption was achieved by the catalysis of ferric-oxalate or ferric-EDTA, the gold leaching rate was low without the extra addition of a probable carcinogen of thiourea.Furthermore, the Fe(III) was rapidly reduced to Fe(II) with the presence of sulfide minerals in actual leach slurry, likely because these minerals catalyzed the oxidation of thiosulfate by Fe(III), which notably impeded gold leaching.Ethanediamine can also complex with Cu 2+ and forms stable cupric-ethanediamine complex [7].The cupric-ethanediamine catalyzed thiosulfate leaching using a synergistic additive of cetyltrimethyl ammonium bromide was applied for a gold bearing ore containing high limonite, in which the gold leaching percentage reached up to 94.3% whilst thiosulfate consumption was as low as 1.12 kg/t-ore [63].However, the development of cupric-ethanediamine catalysis is limited because ethanediamine is poisonous, corrosive, and expensive.
In the last ten years, nickel-and cobalt-based catalysts have been developed.Ninety-five percent of gold in a silicate-type ore was extracted by nickel-ammonia-catalyzed thiosulfate leaching, and thiosulfate consumption was only 1.2 kg/t-ore [44].The dissolved gold in nickel-ammonia-catalyzed ammonium thiosulfate solution can be efficiently recovered by a strongly basic anion exchange resin, and the percentages of gold adsorption and elution are both over 99% because of the lack of interference of [Cu(S 2 O 3 ) 3 ] 5− [64].The extractions of gold and silver from a complex polymetallic sulfide concentrate by copper-and nickel-catalyzed ammoniacal thiosulfate leaching were comparatively studied in our previous work [14].The results showed that thiosulfate consumption during nickel-catalyzed leaching was evidently lower than that of copper catalyzed leaching, and the gold and silver extractions with the nickel catalysis were also comparable  18) and (19).Ni 3 O 4 particles originating from the oxidation of [Ni(NH 3 ) 6 ] 2+ ions are likely to exist in the form of colloidal sol because of their extremely fine size and hydrophilia, thus, solid-state Ni 3 O 4 can easily interact with gold in pulp owing to Brownian motion [14,66].20) and ( 21).The conclusion is supported by the literature [67].Additionally, nickel-citrate and cobalt-EDTA are also found to be able to catalyze thiosulfate leaching through the transformation between the bivalent and trivalent nickel-citrate/cobalt-EDTA complex ions [68,69].
Compared with traditional cupric-ammonia catalysis, the consumptions with the nickel and cobalt catalysts are observably lower because the redox potential of the solution is significantly decreased as a result of the absence of [Cu(NH 3 ) 4 ] 2+ and, furthermore, there is no ammonia pollution.In addition, nickel-citrate and cobalt-EDTA are, respectively, the dominant forms of nickel and cobalt complex ions, which are very different with [Au(S 2 O 3 ) 2 ] 3− at the aspects of size and structure.Thus, the complex ions of nickel and cobalt have little interference with gold recovery by resin adsorption or solvent extraction.
From the above, the replacement of traditional cupric-ammonia catalysis with nickel-and cobalt-based catalysts can not only reduce thiosulfate consumption, but is also beneficial to gold recovery from pregnant thiosulfate solution.Compared with gold leaching, there are fewer studies focusing on gold recovery from aurothiosulfate solution, but these works have indicated that activated carbon adsorption, cementation, electrowinning, and solvent extraction are all likely inapplicable [3,16,18,19,21].
Activated carbon adsorption is a mature and widely applied technology in cyanidation, which is generally used in the form of carbon-in-pulp or carbon-in-leach.However, unfortunately [Au(S 2 O 3 ) 2 ] 3− is very difficult to be adsorbed by activated carbon [70].The low affinity of activated carbon for [Au(S 2 O 3 ) 2 ] 3− may be due to the high negative charge and large size of this ion and weak interaction between carbon active sites and ionic ligand of S 2 O 3 2− [16].Adding cyanide into the pregnant solution can improve the gold recovery by this technique [71], but this is unfavorable from an environmental perspective.Cementation is also a common technique for gold recovery in cyanidation.Pulverized metals, such as zinc, iron, and aluminum, can precipitate gold from thiosulfate leach solution by a displacement reaction.However, unwanted cations are introduced and, thus, complicate the recycle of the solution.
Copper ions as a catalyzer for gold leaching are also precipitated out by these active metals.Copper powder cementation avoids the above problems, but the dissolution of copper raises the redox potential of solution and leads to the re-dissolution of precipitated gold and severe oxidation of thiosulfate [72][73][74].The dosages of pulverized metals used in cementation are far more than theoretical amounts because the metal surfaces are easily passivated in the solution and, hence, the gold content of precipitation product is low [75].
Aurothiosulfate ions can migrate to cathode surface and are reduced into metallic deposit by direct current during electrowinning.However, some metal complex ions such as [Cu(S 2 O 3 ) 3 ] 5− will also be reduced into metals on the surface and contaminate the deposition product.Thiosulfate not only is reduced on cathode, but also gets oxidized on anode [18].Due to these unwanted side reactions, gold product purity and electrowinning efficiency are dramatically decreased, and electric energy input is markedly increased.Furthermore, the recyclable copper ions and thiosulfate in the solution are severely depleted during electrowinning.
It has been proved that aurothiosulfate ions can be enriched in organic phase during solvent extraction employing the extractants of primary, secondary, and tertiary alkylamines, tertiary amine oxides, phosphines, phosphine oxides, phosphate esters, etc. [76][77][78][79].However, the residual of extractant and organic phase in the solution is detrimental to its cycle use, and an enriching operation is required when Au(I) concentration is not high enough.Furthermore, the solution must be clarified to prevent the formation of the third phase that is the immiscible second organic phase between aqueous phase and organic phase, thus, additional plant equipment and processing time are necessary to achieve a complete solid-liquid separation [18].This will bring a considerable increase in capital and operation costs.

Resin Adsorption
The technique of ion exchange resin adsorption has low demand for water quality, and it can be employed in the forms of resin-in-pulp and resin-in-leach [80,81].The elution of loaded resin is at ambient temperature and its regeneration does not require the thermal reactivation and, furthermore, the regeneration procedure can be accomplished during the elution process through an elaborate choice of eluent [82,83].In addition, the functional groups of resins may be designed and tailored to improve adsorption selectivity for aurothiosulfate [18].Thus, resin adsorption technique has attracted increasing attention from researchers.
The ion exchange resins studied to recover gold from thiosulfate leach solution mainly involve weak-base anion resins and strong-base anion resins.The loading capacities of weak-base resins are usually less than 2 kg/t, and furthermore the capacities decrease markedly with the increase of pH in the range of 8-11 [84].The reason for this is that the functional amine groups attached to the polymeric matrix tend to stay in the form of free base under relatively strong alkaline condition and are difficult to be protonated, thus, the ion-exchange ability of resins is damaged at a higher pH than 8. Thus, the weak base resins are not suitable to recover gold from ammoniacal thiosulfate solution whose pH is generally in the range of 9-11 [84,85].
The loading capacities of strong base resins usually reach up to 10-25 kg/t, and are independent of the solution pH.The high capacities make strong base resins more tolerant to competing anions and can efficiently adsorb the extremely low concentration aurothiosulfate [81].However, the selectivity of these resins is poor, and inevitable anions such as [Cu(S 2 O 3 ) 3 ] 5− and polythionate will strongly compete with [Au(S 2 O 3 ) 2 ] 3− for the active sites of resin surface and are co-adsorbed with gold by resins.The co-adsorption of Cu(I) makes the adoption of a two-stage elution process necessary to separate the copper and gold.At first the copper can be selectively eluted by the solutions of oxygenated ammonia-ammonium sulfate, ammonium thiosulfate, etc., thus, a copper rich solution is produced.Then, the gold is able to be effectively eluted by the single component solutions of thiocyanate, polythionates, perchlorate, and nitrate or the two component solutions of thiourea + sulfuric acid and sulfite + chloride [18,83].The elution with single component solutions requires an additional regeneration procedure for resins to regain their loading capacities and avoid the accumulation of elution reagents in leach solution.For the two component solutions, the synergistic reagents of thiourea (TU) and sulfite can form the mixed ligand complexes of [Au(S 2 O 3 )TU] − and [Au(S 2 O 3 )(SO 3 )] 3− through reacting with [Au(S 2 O 3 ) 2 ] 3− , and these two complexes have observably reduced affinity for the resins and, thus, are easily eluted by sulfate and chloride ions, respectively.The SO 4 2− and Cl − on resin surface are easily substituted by [Au(S 2 O 3 ) 2 ] 3− when the eluted resins are returned into pregnant leach solution.Furthermore, these ions have no obvious harmful impact on thiosulfate leaching, which is deduced from the fact that sulfate and chloride both can be used as additives to stabilize Cu(II) during leaching.Thus, the resins have regained their loading capacities during the gold elution process, and the additional regeneration procedure is omitted by use of the two component eluent solutions [83].
The commercial competitiveness of resin adsorption technique is low due to the cost and time involving in operating this complicated two-stage elution process [18].However, if the traditional cupric-ammonia catalysis is replaced by other metals such as nickel and cobalt based catalysts, whose complex ions have weak affinity for the resins, and the co-adsorption of base metals with gold on resin surface will not occur.Thus, the two-stage elution process can be substituted by a simple one-stage process, and the resin adsorption technique for pregnant thiosulfate solution become commercially viable.

Conclusions
Thiosulfate leaching is a promising alternative to cyanidation.Although there have been a great number of studies about thiosulfate leaching of gold in the past several decades, its successful commercial application is rare.The main reasons for this are as follows: thiosulfate consumption is high because thiosulfate itself is metastable and easily oxidized by Cu(II), which is a catalyst for gold leaching and, furthermore, certain associated minerals can accelerate the oxidation; the recovery of dissolved gold in pregnant leach solution is difficult because of the low affinity of activated carbon for [Au(S 2 O 3 ) 2 ] 3− , the complex composition of the solution, and the interference of [Cu(S 2 O 3 ) 3 ] 5− .
The adoption of low reagent concentrations under limited oxygen supply and the regulation of mixed pulp potential via the elaborate adjustment of reaction conditions are both beneficial to reduce thiosulfate consumption.Some additives can be dedicated to stabilize thiosulfate, especially certain organic macromolecular additives that decrease the oxidizing ability of Cu(II) and, furthermore, relieve the catalytic effect of associated minerals on thiosulfate oxidation.The generation of thiosulfate in situ deriving from the oxidation of sulfide minerals is also possible to solve the high consumption problem.However, the replacement of traditional cupric-ammonia catalysis with other metals, such as nickel-and cobalt-based catalysts is the most optimal approach, because it not only reduces thiosulfate consumption observably by decreasing the redox potential of the leach solution significantly, but also eliminates the interference of [Cu(S 2 O 3 ) 3 ] 5− for gold recovery from pregnant thiosulfate solution.
The technique of ion-exchange resin adsorption is suitable for the gold recovery from thiosulfate leach solution because the resin can be employed in the form of resin-in-leach/pulp and be eluted and regenerated simultaneously at ambient temperature through the elaborate choice of eluent.Strong-base anion resins are preferred to weak-base anion resins because their loading capacities are markedly higher and independent of solution pH, but their selectivity for [Au(S 2 O 3 ) 2 ] 3− against [Cu(S 2 O 3 ) 3 ] 5− is low.Thus, a complex and high-cost two-stage elution process is required to separate the copper and gold loaded on the resins.If the traditional cupric-ammonia catalysis is replaced by other metal-based catalysts, whose complex ions have weak affinity for the resins, the two-stage process will be substituted by a simple and low-cost one-stage process.

Figure 1 .
Figure 1.Sketch map of the electrochemical-catalytic mechanism of thiosulfate leaching.

Figure 4 .
Figure 4. Step-oxidation of thiosulfate catalyzed by pyrite.(a) the adsorption of thiosulfate; (b) the transfer of electrons; (c) the formation of reaction products.

Figure 5 .
Figure 5. Oxidation route of sulfur in pyrite.
. The construction of Eh-pH diagram of Ni-NH 3 -S 2 O 3 2− -H 2 O system depicted in Figure 6 was carried out using Outokumpu HSC Chemistry 5.0 (Outotec Oyj, Espoo, Finland), and thermodynamic data were obtained from the database [65].Based on the analysis of this figure in the pH range for thiosulfate leaching (9-11), the catalytic mechanism of nickel-ammonia is proposed as follows: [Ni(NH 3 ) 6 ] 2+ is first oxidized into Ni 3 O 4 then Ni 3 O 4 acts as an oxidant for Au leaching, whilst Ni 3 O 4 itself is reduced back to [Ni(NH 3 ) 6 ] 2+ during the oxidation of Au.The corresponding chemical reactions are indicated as Equations (