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Article

Copper, Zinc, and Lead Recovery from Jarosite Pb–Ag Tailings Waste (Part 2)

Mining and Metallurgy Institute Bor, Zeleni Bulevar 35, 19210 Bor, Serbia
*
Author to whom correspondence should be addressed.
Minerals 2024, 14(8), 791; https://doi.org/10.3390/min14080791
Submission received: 19 June 2024 / Revised: 12 July 2024 / Accepted: 16 July 2024 / Published: 31 July 2024
(This article belongs to the Section Mineral Processing and Extractive Metallurgy)

Abstract

:
The present paper describes the technological solution for obtaining Cu, Zn, Pb, and Ag from jarosite waste raw material, with its simultaneous separation from In and Fe. By roasting at low temperatures, iron was transformed from the Fe2(SO4)3 form into Fe2O3, which is insoluble in water and slightly soluble in acid. Copper sulfate and zinc sulfate are present in jarosite as sulfates. During temperature roasting, the copper and zinc were still in the form of CuSO4 and ZnSO4, i.e., they were easily dissolved in water. This procedure led to good selectivity of Cu and Zn compared to Fe. After water leaching, PbSO4 and Ag2SO4 remained in the solid residue. By treating jarosite with a content of 0.7% Cu, 5.39% Zn, and 5.68% Pb, products of commercial quality were obtained. By roasting jarosite in an electric furnace and leaching the roasted sample in water, leaching degrees of 91.07%, 91.97%, and 9.60% were obtained for Cu, Zn, and Fe, respectively. Using 1 M NaOH in the leaching solution, 99.93% Fe was precipitated to pH = 4. Cu in the form of CuSO4 was further treated by cementation with Zn, after which cement copper was obtained as a commercial product. Zn in the form of ZnSO4 was further treated by precipitation with Na2CO3 to obtain ZnCO3 concentrate of commercial grade. The total recovery of Pb and Ag, which were treated by chloride leaching, was 96.05% and 87.5%, respectively. The resulting NaPbCl3 solution was further treated with Na2CO3 solution, whereby PbCO3 was obtained as a commercial product. The produced PbCO3 could be further subjected to roasting to obtain soluble PbO. In these investigations, PbCO3 was smelted where a Pb anode was obtained; this was electrolytically refined to a Pb cathode. The proposed process does not pollute the environment with As and Cd.

Graphical Abstract

1. Introduction

The demand for increasing metal production and decreasing grades of primary mineral deposits has led researchers to seek alternative methods of pyrometallurgical processing. There has been an increasing share of hydroprocessing plants for secondary raw material treatment since the 1990s [1]. One of these secondary raw materials is jarosite which, in its precipitation process, loses significant amounts of copper, zinc, lead, and silver [2]. The first three are widely used in various branches of the industry. Lead and zinc play important roles in human lives and are widely used in lead–acid batteries, galvanization, rolled and extruded products, alloys, pigments, brass and bronze, and chemicals [3,4,5]. Erdem et al. [6] and Turan et al. [7] conducted important studies on jarosite (zinc plant residue) as a raw material, with the main goal being the recovery of Pb and Zn from jarosite. The demand for lead and zinc increases every year, and by 2050, it will be measured in millions of tons [8]. New lead–zinc deposits have not been discovered in recent years, and exploring the new sources of these metals will be a challenge. Considering that primary ore deposits have been exhausted, secondary raw materials have been gaining increasing importance. The uncertainty surrounding the behavior of jarosite waste has spurred the implementation of metallurgical procedures. Lead is a toxic metal and is discharged as a by-product from different types of industries [9,10,11]. The presence of lead in water resources can cause diseases such as hepatitis and anemia [12,13,14,15]. Researchers have proposed diverse methodologies for recovering valuable minerals from these wastes. Where pyrometallurgical treatment was the primary treatment of such kinds of waste in the past, ecological hydro- and biotechnological procedures are now being increasingly applied. The advantages of the hydrometallurgical technique include high metal recovery, higher tolerance towards impurities, modularity, flexibility, lower energy consumption, and lower capital and operative costs. Several attempts have been made to decompose jarosites using sulfuric acid, hydrochloric acid with the addition of calcium chloride, ammonia, and sodium or calcium hydroxides [16,17,18,19]. Obtaining metal from waste of any kind, solid or liquid, is of great importance [20,21]. Obtaining useful metals from waste can be more energy efficient, economical, and ecological. The opening of new mines requires large investment (connection to infrastructure, excavation, transport, etc.), and, considering that the reserves of useful metals have been depleted in existing mines (low concentrations of metals in the ore) and that their exploitation is unprofitable, the world is increasingly tending to use available resources, such as tailings and other waste.
Various studies have been conducted on the treatment of jarosite, including the following: the co-precipitation of copper and zinc with lead jarosite [22]; the cyanidation of argentian potassium jarosite in alkaline media [23]; sodium arsenojarosite decomposition in alkaline media [24]; the release of arsenic and antimony in alunite–jarosite and beudantite group minerals [25]; the alkaline decomposition of ammonium–sodium jarosite with arsenic [26]; and the thermal decomposition of jarosites with potassium, sodium, and lead [27].
Considering that waste contains harmful and useful metals, and because it is important to add value to useful metals, a new, environmentally acceptable method for the extraction of these useful metals should be proposed.
Our initial studies were focused on the application of different types and conditions of leaching [28], where, in addition to the metals Cu, Zn, and In, more than 80% of Fe was leached. For this reason, further experiments were carried out to convert Fe into insoluble hematite through roasting and water leaching, and to selectively extract Cu, Zn, and In in this way. The roasting and leaching conditions, with selected parameters, are presented in the paper “Indium Recovery from Jarosite Pb–Ag Tailings Waste Part 1” [29].
The roasting of jarosite was conducted at three different temperatures: 530 °C, 570 °C, and 630 °C. The results show that almost all the iron was transformed into hematite in the sample fired at 630 °C, whereas in the samples fired at 530 °C and 570 °C, part of the iron remained in the form of magnetite. Subsequent leaching of the precipitates revealed that the greatest leaching of useful metals was achieved by leaching the precipitates obtained at 530 °C. Copper sulfate and zinc sulfate are present in jarosite as sulfates. They decomposed at 600 °C and 740 °C, respectively. For this reason, at the selected drying temperature, they remained in the form of sulfates that are easily leached in water.
Jarosite Pb–Ag sludge was formed at the Elixir Zorka factory in Šabac, Serbia, and is a valuable residue obtained by leaching with hot acid.
This work represents significant technical support for the valorization of Cu, Zn, Pb, and Ag from jarosite waste and for obtaining products (cement Cu, ZnCO3, PbCO3, and Pb) of commercial quality.

2. Materials and Methods

Analytical Determinations

The acidity of the leach solution was measured using a combined pH electrode Aqua Lytic SD300, produced in Germany. The concentration of zinc, copper, iron, lead, and silver in solution was measured using absorption spectrometry (Perkin-Elmer 403) with a spectrometer produced in the USA. An optical laser particle size analyzer (MASTERSIZER 2000, Hydro2000MU, UK) was used to determine the particle size distribution of the products.
XRD analysis was performed using a “PHILIPS” X-ray diffractometer (Netherlands, model PW-1710/1820, with a curved graphite monochromator and a scintillation counter. The intensities of diffracted CuKα X-ray radiation (λ = 1.54178 Å) were measured at room temperature in intervals of 0.02° (2θ), with a time of 1 s, over a range from 4 to 65° (2θ).
Electron microscopy method: The sample was coated with gold (20 nm layer, density 2.25 g/cm3). The textual part was accompanied by electron micrographs and SEM chemical spectra. SEM model: JEOL JSM-7001F—Magnification X 5-1,000,000 (Japan).
The reduction melting of PbCO3 was performed in the electric furnace by FIOA, Italy.

3. Results and Discussion

3.1. Chemical and Mineralogical Analysis of Jarosite

Homogenization was performed and a representative sample was sent for chemical and mineralogical analysis. The chemical analysis of the sample is shown in Table 1.
The diffractogram obtained from the XRD analysis of the jarosite waste sample is shown in [29]. The presented minerals are jarosite in the form of NH4Fe3(SO4)2(OH)6, magnetite in the form of Fe3O4, and anglesite in the form of PbSO4.
There is a possibility that Zn is in the jarosite structure. The detection limit is about 1%. Jarosite and magnetite raise the baseline of the diffractogram because they contain a large proportion of Fe, which creates secondary fluorescent radiation that is scattered everywhere. As a result, the detection limit is higher than 3–5%, meaning that crystalline phases containing Zn may be below the detection threshold.
There is a possibility that zinc is present in the form of an amorphous substance that cannot be detected.
Magnetite belongs to the spinel group, so the presence of other minerals from the spinel group that have peaks that coincide with magnetite is also possible. Therefore, there is a possibility that zinc minerals in the sample may be present in the form of zinc-ferrite, franklinite, and granite.

3.2. Roasting and Leaching of Jarosite Pb–Ag Deposits

Detailed laboratory tests of the combined process, which includes roasting the jarosite Pb–Ag sample and leaching the resulting product (calcine), were performed. The results are presented in [29]. The accepted treatment parameters for Pb–Ag jarosite sample include roasting for 4 h at a temperature of 530 °C and leaching of the calcine with water at a solid–liquid phase ratio of 1:5 for 1 h, during which high leaching of the examined metals and low iron leaching obtained Cu and Zn. The conditions of the combined process and the obtained results of percentage metal leaching are shown in Table 2.
From Table 2, it can be seen that under the applied conditions of roasting and leaching, the recovery amounts of Cu, Zn, and Fe were 91.07%, 91.97%, and 9.6%, respectively. It can also be observed from the results that after the roasting of jarosite and the leaching of the calcine in water, the measured pH of the solution was 2.25.
After leaching, Pb and Ag remained in the solid leach residue.

3.3. Treatment of Sulfate Solution

A sulfate solution containing Cu, Zn, Fe, and In was treated to separate the metals. During the precipitation phase, the pH level was controlled and maintained at 4 using a concentrated NaOH solution. The detailed procedure is described in [29].

3.4. Cementation of Cu from the Solution after the Precipitation of Fe

After precipitation, the macro-components Cu and Zn remained in the solution, which were present in the solution in the form of sulfates, specifically CuSO4 and ZnSO4, respectively. To selectively extract copper from the solution, cementation was performed at a pH of 2 with zinc powder, a metal that is more electronegative than copper. The necessary amount of zinc for the cementation process was calculated based on the stoichiometrically required amount with 50% excess. The process of cementation, during which copper is converted into cement slurry, takes place according to reaction (1).
CuSO4 + Zn↓ → ZnSO4 + Cu↓
The obtained cement copper was washed, dried, and subjected to chemical analysis. Characterization of the obtained cement copper showed that the metal content in it was as follows: Cu = 75.97%, Zn = 7.31%, Fe = 0.005%, In < 0.095%, S = 1.9%, Ga < 0.002%, Ge < 0.002%, Ag = 0.042%, and Pb = 0.06%.
In the leaching phase, copper was not completely leached but was recovered at 91.07%, which means that the loss in this phase was 8.93%.
Copper losses occurred during indium precipitation and copper cementation, amounting to 11.3%. During the precipitation process, approximately two-thirds of the total 11.3% of Cu remained trapped (occluded) in the precipitate and the remaining one-third of the total 11.3% was not fully cemented because the cementation process was never completed.
The product Cem Cu was offered to the ZiJin Copper Bor Srbija smelter. The limiting factors for product quality were as follows: 3% moisture content, up to 5% Pb, up to 8% Zn, and granulometric composition for treatment in the smelter.
The offered product was accepted by the company for further processing and to obtain cathodic copper.

3.4.1. Granulometric Analysis of Cement Copper

A granulometric analysis of cement copper was performed, and the results are shown in Figure 1.
From the results of the granulometric composition of the sample, it can be observed that the size class of 50.258 μm is represented by 90%, the size class of 23.019 μm is represented by 50%, and the size class of 8.157 μm is represented by 10%.

3.4.2. SEM-EDS Analysis of Cement Copper

The diffractogram of Cu cement samples is shown in Figure 2. Copper (Cu) and cuprite (Cu2O) crystalline phases were identified in the Cu cement sample. Copper is more present in the sample than cuprite.
The presence of the elemental copper crystalline phase was determined in the analyzed sample. The sample was very homogeneous. The elemental copper content was much more present, whereas the rest was copper oxide. Photomicrographs of the tested sample are shown in Figure 3.
Figure 4 shows the chemical spectrum of spectrum 61, which was mapped using photomicrograph 3.
Table 3 presents the results of the chemical analysis of the summary spectrum of the cement copper sample.
Figure 5 presents the mapping of the entire surface of the sample, highlighting the distribution of the copper element.

3.5. Precipitation of ZnCO3 from the Solution after the Cementation of Cu

After copper cementation, the solution was filtered and prepared to obtain ZnCO3 from ZnSO4. The pH value of the solution after Cu cementation was measured as 2.84. The precipitation of Zn as ZnCO3 was achieved by adding 10% Na2CO3 solution until the pH reached 8. The precipitation process of Zn as ZnCO3 occurs according to reaction (2).
ZnSO4 + Na2CO3 → ZnCO3↓ + Na2SO4
The resulting zinc carbonate was washed, dried, and subjected to chemical analysis. Characterization of the obtained zinc carbonate showed the following composition: Zn = 52.22%, Cu = 0.26%, Fe = 0.84%, Pb = 0.002%, Ag < 0.001%, S = 2.24%, and In < 0.002%.
The obtained ZnCO3 product, along with the presented analysis, was offered to KCM Bulgaria Company. The company itself analyzed the product and determined that the content of As and Cd metals was <0.001% and 0.14%, respectively, and that the quality of the product met their needs. The offered product was accepted by the company for further processing and to obtain cathodic zinc.

3.5.1. Granulometric Analysis of ZnCO3

A granulometric analysis of zinc carbonate was performed, and the results are shown in Figure 6.
From the results of the granulometric composition of the sample, it can be observed that the size class of 65.035 μm is represented by 90%, the size class of 18.052 μm is represented by 50%, and the size class of 3.214 μm is represented by 10%.

3.5.2. SEM-EDS Analysis of ZnCO3

The diffractogram of the following crystalline phases was determined in the analyzed sample and is presented in Figure 7, including ZnCO3, ZnO, Zn5(CO3)2(OH)6, and CaCO3.
A photomicrograph of the tested sample is shown in Figure 8.
Figure 9 shows the chemical spectrum of spectrum 3, which was mapped using photomicrograph 8 of the analyzed sample.
Table 4 shows the results of the chemical analysis of the spectrum of the zinc carbonate sample.

3.6. Characterization of the Solution after the Precipitation of ZnCO3

The characterization of wastewater after ZnCO3 precipitation is shown in Table 5.
Based on the results shown in Table 5, it can be concluded that the emission limit values of polluting substances in the technological wastewater, before their discharge into the public sewage system, meet the limit values.
The resulting wastewater can be returned to the process as technical return water and used for leaching the calcine.

3.7. Chloride Leaching of the Solid Residue with NaCl

After calcine leaching in water, a solid residue containing PbSO4 was subjected to chloride leaching in NaCl in order to leach Pb. The leaching conditions were as follows: a salt concentration of 250 g/L NaCl, a solid–liquid phase ratio of 1:20, a temperature of 80 °C, and a leaching time of 20 min. These conditions were determined in our earlier research when polymetallic raw material was leached [30]. The results of metal leaching are shown in Table 6.
After chloride leaching, a solution of NaPbCl3 was obtained. The measured pH value of the solution was 6.86. The precipitation of Pb in the form of PbCO3 was achieved by adding 10% Na2CO3 solution until the pH reached 8.
The precipitation of PbCO3 takes place according to reaction (3).
NaPbCl3 + Na2CO3 → PbCO3↓ + 3NaCl
Characterization of the obtained lead carbonate showed the following content: Pb = 67.50%, Ag = 0.47%, Cu = 0.55%, Zn = 5.63%, Fe = 0.08%, S = 0.14%, and In < 0.06%.

3.7.1. Granulometric Analysis of PbCO3

A granulometric analysis of lead carbonate was performed, and the results are shown in Figure 10.
From the results of the granulometric composition of the sample, it can be observed that the size class of 28.629 μm is represented by 90%, the size class of 10.976 μm is represented by 50%, and the size class of 3.966 μm is represented by 10%.

3.7.2. SEM-EDS Analysis of PbCO3

The diffractogram of PbCO3 samples is shown in Figure 11. In the PbCO3 sample, the crystalline phases are sodium–lead–carbonate–hydroxide (NaPb2(CO3)2OH), sanromanite (Na2CaPb3(CO3)5), cerusite (PbCO3), and lauronite (Pb(OH)Cl). Sodium–lead–carbonate–hydroxide and sanromanite are more abundant in the sample than cerusite and lauronite.
Photomicrographs of the tested sample are shown in Figure 12.
Figure 13 shows the chemical spectrum of spectrum 37, which was mapped using photomicrograph 12 of the analyzed sample.
Table 7 shows the results of the chemical analysis of spectrum 37 of the lead carbonate sample.
Figure 14 presents the mapping of the entire surface of the sample, showing the distribution of lead, calcium, and oxygen elements.
XRD shows the crystalline phase of the product and the form in which it is present. SEM-EDS was performed to unequivocally confirm the presence of Cucem, ZnCO3, and PbCO3. The percentage content on the spectra does not show the metal content in the analyzed sample; yet, based on the percentage ratios in the spectrum, it indicates the phase ratio and shows the compound.
The copper content in the cement suspension was determined using the electrogravimetric method. The content of Zn in ZnCO3 and Pb in PbCO3 was determined by dissolving them and determining the metal content using volumetric titration. Based on the calculations, the metal content in the products was determined. Chemical analysis is a precise quantitative analysis that shows the exact composition of the product.
The appearance of Au in the spectra is due to the steam up of samples using gold during the preparation process for SEM-EDS analysis.
The practical importance of determining the granulometric composition of the obtained products is that it allows the future customer to understand in which part of the production process can be applied, considering that these are commercial products.

3.8. Processing of PbCO3

PbCO3 can be roasted at 550 °C to obtain PbO, which can be sold. However, in our investigation, PbCO3 was melted at 950 °C to produce the Pb anode. This Pb anode was further treated through electro-refining to obtain the Pb cathode (Figure 15).
The mixtures for reduction melting were as follows: 81 g of PbCO3, 66 g of Na2CO3, 33 g of Borax, and 16 g of carbon. When melting PbCO3, the following reactions occur:
PbCO3 → PbO + CO2
2PbO + C → Pb + CO2
Raw lead (lead anode) was obtained through the reduction smelting of lead oxide. After melting, the raw lead was poured and a seal was made, which was rolled into the anode. The rolled Pb anode was further subjected to electrolytic refining.

Electrolytic Refining of the Pb Anode

Cathodic lead is obtained through the electrolysis of raw lead, according to the following reactions:
Cathode: Pb(CH3SO3)2 + 2e→PbO + 2CH3SO3
Anode: H2O → ½O2 + 2H+ + 2e
The electrolyte for electrolytic lead refining is obtained by dissolving lead oxide or lead carbonate in methane-sulfonic acid, according to the following reactions:
PbO + 2CH3SO3H → Pb(CH3SO3)2 + H2O
PbCO3 + 2CH3SO3H → Pb(CH3SO3)2 + H2O + CO2
The conditions for anode lead refining were as follows: methane-sulfonic acid at 100 g/L, Pb at 200 g/L, organic additive (polyethylene glycol) at 0.25 g/L, a temperature of 20–30 °C, and a Dk of 1.5–3 A/dm2.
Commercial-quality lead with 99.95% purity was obtained through the electrolytic refining of lead anodes.
Pb was further used in MMI Bor as a collector during cupellation for the analytical determination of Au and Ag in the samples.

3.9. TCLP and LP Test of Solid Residue after Pb and Ag Leaching

After Pb and Ag leaching, the LP test of the solid residue and the TCLP (Toxicity Characteristic Leaching Procedure) test were performed. The solid residue was examined for disposal. The waste was examined using a leachability test and a toxicity test. The results of the LP test are shown in Table 8. The results of the TCLP test are shown in Table 9.
The results of the leachability test (LP test) showed that the waste was non-hazardous. The TCLP test showed that the waste had no toxic characteristics and could be disposed of in landfill as non-hazardous waste.

3.10. Treatment of the Solution After PbCO3 Precipitation

After PbCO3 precipitation, the precipitation solution was adjusted to a concentration of 250 g/L of NaCl for reuse in PbSO4 leaching.
If the solution contained increased concentrations of impurities (Fe, Cu, Zn, Ag, SO42−, etc.), it could be treated with NaOH solution until a pH of 10 was reached to precipitate residual silver in the form of Ag2O. The Ag2O precipitate can be further reduced with hydrazine and melted to obtain pure Ag.
The filtrate is chloride wastewater, which is then further purified at a chloride wastewater treatment plant.

3.11. Proposal for a Technological Scheme for the Treatment of Jarosite Pb–Ag Tailings

The proposed technological scheme for obtaining Cu, Zn, and Pb from jarosite waste, including a material balance, is shown in Figure 16.

4. Conclusions

Copper, zinc, lead, and silver from jarosite tailings waste were extracted through the following treatment phases: (I) the roasting of jarosite to convert ferric sulfate to water-insoluble hematite and (II) leaching Cu and Zn with water to obtain a CuSO4 + ZnSO4 solution.
There was also insignificant dissolution of Fe because the following stages were conducted: (III) the precipitation of Fe from the leach solution with 1 M NaOH, (IV) the cementation of Cu with zinc from the CuSO4 + ZnSO4 solution, (V) the precipitation of Zn from the ZnSO4 solution with Na2CO3, (VI) leaching of the solid residue obtained after water leaching with NaCl to dissolve Pb and its precipitation as PbCO3 with Na2CO3, and (VII) PbCO3 was further melted to obtain a Pb anode, which was then converted into a Pb cathode by electrolytic refining.
This work shows that the combination of roasting and leaching provides a promising process for obtaining Cu cement, ZnCO3, PbCO3, and Pb in the form of commercial products.
The total recovery of Cu and Zn after roasting, leaching, Fe precipitation, cementation, and carbonate precipitation was 79.73% and 86.64%, respectively. The total recovery of Pb and Ag after chloride leaching was 96.05% and 87.5%, respectively. The technological scheme, along with the material balance, is presented in this paper.
The quality of the obtained products was as follows:
The composition of Cu cement was Cu = 75.97%, Zn = 7.31%, Fe = 0.005%, In < 0.095%, S = 1.9%, Ga < 0.002%, Ge < 0.002%, Ag = 0.042%, and Pb = 0.06%.
The composition of ZnCO3 was Zn = 52.22%, Cu = 0.26%, Fe = 0.84%, Pb = 0.002%, Ag < 0.001%, S = 2.24%, and In < 0.002%.
The composition of PbCO3 was Pb = 67.50%, Ag = 0.47%, Cu = 0.55%, Zn = 5.63%, Fe = 0.08%, S = 0.14%, and In < 0.06%.
Pb = 99.95%.
The obtained results were confirmed at an enlarged pilot level, after which the design of the plant was initiated by Elixir Company in Šabac, Serbia.

Author Contributions

Conceptualization, V.C.; methodology, V.C. and M.J.; investigation, D.S.B., Lj.A. and I.J.; writing—original draft preparation, V.C. and M.J.; writing—review and editing, D.M.B.; supervision, S.Đ. All authors have read and agreed to the published version of the manuscript.

Funding

The authors would like to thank Elixir Zorka, Serbia, for providing the sample and for their financial support in obtaining a solution to manage this waste (contract number 1061/19).

Data Availability Statement

Data are contained within this article.

Acknowledgments

This work was supported by the Ministry of Science, Technological Development, and Innovation of the Republic of Serbia under the contract on realization, and the financing of scientific research by the Mining and Metallurgy Institute Bor in 2024 (contract number: 451-03-66/2024-03/200052).

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Graphic representation of the content of the identified size classes and the granulometric sample composition of Cem Cu, showing the average undersize distribution curve values.
Figure 1. Graphic representation of the content of the identified size classes and the granulometric sample composition of Cem Cu, showing the average undersize distribution curve values.
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Figure 2. Diffractogram of cement copper.
Figure 2. Diffractogram of cement copper.
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Figure 3. Photomicrograph of elemental copper in the “Cu cement” sample.
Figure 3. Photomicrograph of elemental copper in the “Cu cement” sample.
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Figure 4. Chemical spectrum from Figure 3 (spectrum 61).
Figure 4. Chemical spectrum from Figure 3 (spectrum 61).
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Figure 5. Copper mapping image. Mapping of the copper element from Figure 3.
Figure 5. Copper mapping image. Mapping of the copper element from Figure 3.
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Figure 6. Graphic representation of the content of the identified size classes and the granulometric sample composition of ZnCO3, showing the average undersize distribution curve values.
Figure 6. Graphic representation of the content of the identified size classes and the granulometric sample composition of ZnCO3, showing the average undersize distribution curve values.
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Figure 7. Diffractogram of the ZnCO3 sample.
Figure 7. Diffractogram of the ZnCO3 sample.
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Figure 8. Photomicrograph of the ZnCO3 phase.
Figure 8. Photomicrograph of the ZnCO3 phase.
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Figure 9. Chemical spectrum from Figure 8 (spectrum 3).
Figure 9. Chemical spectrum from Figure 8 (spectrum 3).
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Figure 10. Graphic representation of the content of the identified size classes and the granulometric sample composition of PbCO3, showing the average undersize distribution curve values.
Figure 10. Graphic representation of the content of the identified size classes and the granulometric sample composition of PbCO3, showing the average undersize distribution curve values.
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Figure 11. Diffractogram of the PbCO3 sample.
Figure 11. Diffractogram of the PbCO3 sample.
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Figure 12. Photomicrograph of PbCO3.
Figure 12. Photomicrograph of PbCO3.
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Figure 13. Chemical spectrum from Figure 12 (spectrum 37).
Figure 13. Chemical spectrum from Figure 12 (spectrum 37).
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Figure 14. Lead mapping images. (a) Mapping the lead element from Figure 12. (b) Mapping the calcium element from Figure 12. (c) Mapping the oxygen element from Figure 12.
Figure 14. Lead mapping images. (a) Mapping the lead element from Figure 12. (b) Mapping the calcium element from Figure 12. (c) Mapping the oxygen element from Figure 12.
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Figure 15. Smelting of PbCO3 and the refinement of Pb: (a) smelting, (b) casting, (c) Pb anode, and (d) Pb cathode.
Figure 15. Smelting of PbCO3 and the refinement of Pb: (a) smelting, (b) casting, (c) Pb anode, and (d) Pb cathode.
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Figure 16. Technological scheme for obtaining Cu, Zn, and Pb from jarosite waste.
Figure 16. Technological scheme for obtaining Cu, Zn, and Pb from jarosite waste.
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Table 1. Chemical analysis of the Pb–Ag jarosite sample.
Table 1. Chemical analysis of the Pb–Ag jarosite sample.
ElementCu
%
Zn
%
Fe
%
Ag
%
Pb
%
In
%
S
%
N2
%
H2
%
C
%
Content0.75.3930.610.0345.680.03439.611.3151.6700.126
Table 2. Conditions for the jarosite roasting and leaching process.
Table 2. Conditions for the jarosite roasting and leaching process.
Roasting Time 4 hLeaching with H2O (Solid–Liquid = 1:5),
t = 1 h and pH after Leaching
Recovery
Sample Mass
(g)
Roasting Temperature
(°C)
pHCu
%
Zn
%
Fe
%
1.1005302.2591.0791.979.60
Table 3. Chemical composition from Figure 4 (spectrum 61).
Table 3. Chemical composition from Figure 4 (spectrum 61).
Spectrum 61
ElementLine TypeWeight %Weight % Sigma
CuK series100.000.00
Total 100.00
Table 4. Chemical composition from Figure 9 (spectrum 3).
Table 4. Chemical composition from Figure 9 (spectrum 3).
Spectrum 3
ElementLine TypeWeight %Weight % Sigma
CK series15.730.67
OK series29.150.28
SK series0.070.03
ClK series0.020.02
CaK series2.920.04
MnK series5.370.07
FeK series0.050.03
CuK series0.510.05
ZnK series44.660.39
CdL series1.520.06
Total 100.00
Table 5. Characterization of wastewater after ZnCO3 precipitation.
Table 5. Characterization of wastewater after ZnCO3 precipitation.
ParameterUnit of MeasureTest ResultEmission Limit Value
pH 8.06.5–9.5
Chemical consumption of oxygenmg/L7.341000
Biochemical consumption of oxygenmg/L24500
Total inorganic nitrogen N (NH3-N, NO3-N, NO2-N)mg/L1.15120
Total nitrogen, Nmg/L1.472150
Ammonia, NH4-Nmg/L0.37100
Precipitable substances after 10 min mg/L<0.2150
Phosphorus, Pmg/L<0.0320
Extract with organic solventsmg/L<0.0550
Mineral oilsmg/L<0.0530
Total saltsmg/L1425000
Phenolsmg/L<0.150
Sulfates, SO42−mg/L83.7400
Chlorides, Clmg/L9.4730
Fluorides, Fmg/L1.3050
Sulfides, S2−mg/L<0.0055
Arsenic, As mg/L<0.020.2
Copper, Cumg/L0.0092
Barium, Bamg/L<0.0090.5
Zinc, Znmg/L0.1962
Iron, Femg/L<0.007200
Chrome, Crmg/L<0.0051
Chrome, Cr6+mg/L<0.0050.5
Cadmium, Sdmg/L0.0450.1
Tin, Snmg/L<0.052
Cobalt, Comg/L0.0621
Manganese, Mnmg/L0.0065
Molybdenum, Momg/L<0.0070.5
Nickel, Nimg/L0.0371
Lead, Pbmg/L<0.020.2
Silver, Agmg/L<0.0050.2
Mercury, Hgmg/L<0.00050.05
Table 6. Percentage of metal recovery in the process of chloride leaching of the solid residue.
Table 6. Percentage of metal recovery in the process of chloride leaching of the solid residue.
Metal RecoveryPb %Ag %Fe %Cu %Zn %
96.0587.500.026.227.51
Table 7. Chemical composition from Figure 13 (spectrum 37).
Table 7. Chemical composition from Figure 13 (spectrum 37).
Spectrum 37
ElementLine TypeWeight %Weight % Sigma
CK series21.320.39
OK series4.450.12
AlK series0.120.02
ClK series12.070.09
CuK series8.160.09
ZnK series1.990.07
PbM series51.890.29
Total 100.00
Table 8. Results of the chemical test of the solid residue: LP test.
Table 8. Results of the chemical test of the solid residue: LP test.
ParameterUnitFound ValueReference Value for
Inert Waste
Reference Value for
Non-Hazardous Waste
Reference Value for
Hazardous Waste
Antimony, Sbmg/kg × dm<0.110.060.75
Arsenic, Asmg/kg × dm<0.20.5225
Copper, Cumg/kg × dm0.07250100
Barium, Bamg/kg × dm0.1320100300
Cadmium, Cdmg/kg × dm<0.080.0415
Molybdenum, Momg/kg × dm<0.150.51030
Nickel, Nimg/kg × dm<0.070.41040
Lead, Pbmg/kg × dm0.200.51050
Selenium, Semg/kg × dm<0.330.10.57
Chrome, Crmg/kg × dm<0.050.51070
Zinc, Znmg/kg × dm0.6450200
Mercury, Hgmg/kg × dm<0.0050.010.22
SO42−mg/kg × dm900100020,00050,000
Clmg/kg × dm12080015,00025,000
Fmg/kg × dm<810150500
Table 9. Results of the physical and chemical tests for the toxic characteristics of the solid residue intended for disposal: TCLP test.
Table 9. Results of the physical and chemical tests for the toxic characteristics of the solid residue intended for disposal: TCLP test.
ParameterUnitFound ValueReference Value for
Non-Hazardous Waste
Antimony, Sbmg/L<0.01115
Barium, Bamg/L0.09100
Chrome, Crmg/L<0.0055
Molybdenum, Momg/L<0.007350
Nickel, Nimg/L<0.03620
Selenium, Semg/L<0.0331
Zinc, Znmg/L1.72250
Copper, Cumg/L<0.00525
Arsenic, Asmg/L<0.0205
Cadmium, Cdmg/L0.721
Lead, Pbmg/L<0.0205
Mercury, Hgmg/L<0.00050.2
Vanadium, Vmg/L<0.00824
Silver, Agmg/L<0.0055
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MDPI and ACS Style

Conić, V.; Janošević, M.; Božić, D.S.; Avramović, L.; Jovanović, I.; Bugarin, D.M.; Đorđievski, S. Copper, Zinc, and Lead Recovery from Jarosite Pb–Ag Tailings Waste (Part 2). Minerals 2024, 14, 791. https://doi.org/10.3390/min14080791

AMA Style

Conić V, Janošević M, Božić DS, Avramović L, Jovanović I, Bugarin DM, Đorđievski S. Copper, Zinc, and Lead Recovery from Jarosite Pb–Ag Tailings Waste (Part 2). Minerals. 2024; 14(8):791. https://doi.org/10.3390/min14080791

Chicago/Turabian Style

Conić, Vesna, Miloš Janošević, Dragana S. Božić, Ljiljana Avramović, Ivana Jovanović, Dejan M. Bugarin, and Stefan Đorđievski. 2024. "Copper, Zinc, and Lead Recovery from Jarosite Pb–Ag Tailings Waste (Part 2)" Minerals 14, no. 8: 791. https://doi.org/10.3390/min14080791

APA Style

Conić, V., Janošević, M., Božić, D. S., Avramović, L., Jovanović, I., Bugarin, D. M., & Đorđievski, S. (2024). Copper, Zinc, and Lead Recovery from Jarosite Pb–Ag Tailings Waste (Part 2). Minerals, 14(8), 791. https://doi.org/10.3390/min14080791

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