TY  - CONF
AU  - Đokić, Jovana
AU  - Gajić, Nataša
AU  - Anđić, Dimitrije
AU  - Kamberović, Željko
PY  - 2023
UR  - https://ritnms.itnms.ac.rs/handle/123456789/1234
AB  - During the conventional roast–leach–electrolysis (RLE) zinc production process,
precipitation of the jarosite-type compounds is widely used to remove iron and other metal
impurities from the solution. Above mentioned compounds, with the general formula
MFe3(SO4)2(OH)6, (M+=NH4, Na, K, Ag, etc.), in addition to iron, contain a high
concentration of Pb, Cd, Cr, As, Zn, In, Ga, Ge as metal oxides and/or sulfates [1].
Consequently, jarosite is considered hazardous yet valuable waste [2]. In addition, every
year around 6-7 million tonnes of jarosite waste is generated globally [3]. Due to large waste
volumes and its chemical characteristics, jarosite requires a lot of storage space and
monitoring. Unfortunately, this type of waste is often landfilled causing serious
environmental problems and irreversible metal and value losses. Hence, an urgent solution
for both managing and utilization/recycling is required, to face needs regarding ecological
demands and circular economy goals.
In this paper, jarosite sludge, as a specific type of hazardous industrial waste, is used
to investigate transformation to the targeted compounds through the comprehensive
thermodynamic analysis and experimental roasting process tests. The roasting was
conducted to transform iron into insoluble hematite (Fe2O3), valuable metals (Zn, Cu, and
In) into water-soluble sulfates, and to keep Pb in the form of water-insoluble anglesite
(PbSO4). The solid residue obtained after roasting was used in leaching tests to further
evaluate the efficiency of the targeted phase transformations.
Theoretical considerations of chemical reactions and phase thermodynamics were
performed using the HSC Chemistry v.9.2.3 software [4] to define potential chemical
reactions, examine the feasibility of the target transformations, and set the limiting reaction
parameters. Further, in the first part of the experimental work, the influence of the roasting
process and reaction parameters on the transformation of jarosite sludge phases into target
compounds was investigated. This included variations in the reaction time, temperature, and
furnace atmosphere influence. The leaching conditions were kept constant (temperature of
25 °C, during 60 min, and solid to liquid ratio of 1/5) to determine the efficiency of phase
transformations in the samples obtained by roasting. Changes in the chemical and
mineralogical composition and microstructure were analyzed using different analytical
methods, including XRD and SEM analysis.
According to the obtained results of the roasting process, it was determined that the
phase transformation of jarosite sludge compounds into targeted insoluble hematite and
water-soluble sulfates occurs at 730 °C, the time required is 60 min in the air (oxidizing) atmosphere of 1-2 [dm3/h]/kg of the input material, which is in accordance with the results
of the theoretical indications. Also, it is experimentally confirmed that the introduction of
sulfate into the roasting atmosphere leads to the incomplete transformation of jarosite and
the formation of the unwanted Fe2(SO4)3. Leaching results of the sample obtained by the
abovementioned optimal roasting conditions show that only 4.5 % of Fe is leached while
the rest remains as solid targeted hematite. Also, more than 75 % of In and more
than 90 % of other targeted metals (Cu and Zn) are leached, indicating the high efficiency
of the roasting process. Phase transformation was confirmed by SEM analysis, showing that
hexagonal crystals of jarosite, dominating in the starting material, were completely replaced
with the globular microstructure of Fe2O3, in the roasted samples. SEM analysis of the
leaching residue also confirmed the absence of the water-soluble sulfates and the presence
of the anglesite as water-insoluble sulfate. The phase composition of the samples is
confirmed by XRD analysis.
This research shows that the proposed process enables the recycling of jarosite through
metal transformation and further utilization. The obtained products can be used in industry,
while the metal ions can be selectively separated from the sulfate solution and returned to the
production streams. This approach contributes to the utilization of jarosite, as hazardous
waste, in order to obtain valuable metals, and generally reduces the negative environmental
impact by decreasing the amount of disposed waste and reducing the need for primary
exploitation.
PB  - Beograd : Srpsko hemijsko društvo
C3  - 9. simpozijum Hemija i zaštita životne sredine EnviroChem2023
T1  - Jarosite sludge - utilization and valuable metals recovery applying roasting-leaching process
EP  - 180
SP  - 179
ER  - 

@conference{
author = "Đokić, Jovana and Gajić, Nataša and Anđić, Dimitrije and Kamberović, Željko",
year = "2023",
abstract = "During the conventional roast–leach–electrolysis (RLE) zinc production process,
precipitation of the jarosite-type compounds is widely used to remove iron and other metal
impurities from the solution. Above mentioned compounds, with the general formula
MFe3(SO4)2(OH)6, (M+=NH4, Na, K, Ag, etc.), in addition to iron, contain a high
concentration of Pb, Cd, Cr, As, Zn, In, Ga, Ge as metal oxides and/or sulfates [1].
Consequently, jarosite is considered hazardous yet valuable waste [2]. In addition, every
year around 6-7 million tonnes of jarosite waste is generated globally [3]. Due to large waste
volumes and its chemical characteristics, jarosite requires a lot of storage space and
monitoring. Unfortunately, this type of waste is often landfilled causing serious
environmental problems and irreversible metal and value losses. Hence, an urgent solution
for both managing and utilization/recycling is required, to face needs regarding ecological
demands and circular economy goals.
In this paper, jarosite sludge, as a specific type of hazardous industrial waste, is used
to investigate transformation to the targeted compounds through the comprehensive
thermodynamic analysis and experimental roasting process tests. The roasting was
conducted to transform iron into insoluble hematite (Fe2O3), valuable metals (Zn, Cu, and
In) into water-soluble sulfates, and to keep Pb in the form of water-insoluble anglesite
(PbSO4). The solid residue obtained after roasting was used in leaching tests to further
evaluate the efficiency of the targeted phase transformations.
Theoretical considerations of chemical reactions and phase thermodynamics were
performed using the HSC Chemistry v.9.2.3 software [4] to define potential chemical
reactions, examine the feasibility of the target transformations, and set the limiting reaction
parameters. Further, in the first part of the experimental work, the influence of the roasting
process and reaction parameters on the transformation of jarosite sludge phases into target
compounds was investigated. This included variations in the reaction time, temperature, and
furnace atmosphere influence. The leaching conditions were kept constant (temperature of
25 °C, during 60 min, and solid to liquid ratio of 1/5) to determine the efficiency of phase
transformations in the samples obtained by roasting. Changes in the chemical and
mineralogical composition and microstructure were analyzed using different analytical
methods, including XRD and SEM analysis.
According to the obtained results of the roasting process, it was determined that the
phase transformation of jarosite sludge compounds into targeted insoluble hematite and
water-soluble sulfates occurs at 730 °C, the time required is 60 min in the air (oxidizing) atmosphere of 1-2 [dm3/h]/kg of the input material, which is in accordance with the results
of the theoretical indications. Also, it is experimentally confirmed that the introduction of
sulfate into the roasting atmosphere leads to the incomplete transformation of jarosite and
the formation of the unwanted Fe2(SO4)3. Leaching results of the sample obtained by the
abovementioned optimal roasting conditions show that only 4.5 % of Fe is leached while
the rest remains as solid targeted hematite. Also, more than 75 % of In and more
than 90 % of other targeted metals (Cu and Zn) are leached, indicating the high efficiency
of the roasting process. Phase transformation was confirmed by SEM analysis, showing that
hexagonal crystals of jarosite, dominating in the starting material, were completely replaced
with the globular microstructure of Fe2O3, in the roasted samples. SEM analysis of the
leaching residue also confirmed the absence of the water-soluble sulfates and the presence
of the anglesite as water-insoluble sulfate. The phase composition of the samples is
confirmed by XRD analysis.
This research shows that the proposed process enables the recycling of jarosite through
metal transformation and further utilization. The obtained products can be used in industry,
while the metal ions can be selectively separated from the sulfate solution and returned to the
production streams. This approach contributes to the utilization of jarosite, as hazardous
waste, in order to obtain valuable metals, and generally reduces the negative environmental
impact by decreasing the amount of disposed waste and reducing the need for primary
exploitation.",
publisher = "Beograd : Srpsko hemijsko društvo",
journal = "9. simpozijum Hemija i zaštita životne sredine EnviroChem2023",
title = "Jarosite sludge - utilization and valuable metals recovery applying roasting-leaching process",
pages = "180-179"
}

Đokić, J., Gajić, N., Anđić, D.,& Kamberović, Ž.. (2023). Jarosite sludge - utilization and valuable metals recovery applying roasting-leaching process. in 9. simpozijum Hemija i zaštita životne sredine EnviroChem2023
Beograd : Srpsko hemijsko društvo., 179-180.

Đokić J, Gajić N, Anđić D, Kamberović Ž. Jarosite sludge - utilization and valuable metals recovery applying roasting-leaching process. in 9. simpozijum Hemija i zaštita životne sredine EnviroChem2023. 2023;:179-180..

Đokić, Jovana, Gajić, Nataša, Anđić, Dimitrije, Kamberović, Željko, "Jarosite sludge - utilization and valuable metals recovery applying roasting-leaching process" in 9. simpozijum Hemija i zaštita životne sredine EnviroChem2023 (2023):179-180.

TY  - JOUR
AU  - Sokić, Miroslav
AU  - Stojanović, Jovica
AU  - Marković, Branislav
AU  - Kamberović, Željko
AU  - Gajić, Nataša
AU  - Radosavljević-Mihajlović, Ana
AU  - Milojkov, Dušan
PY  - 2022
UR  - https://ritnms.itnms.ac.rs/handle/123456789/607
AB  - This paper examines the effects of structural-textural characteristics of sulfide minerals on their leaching from polymetallic concentrates with sulfuric acid and hydrogen peroxide solutions. The polymetallic concentrate was obtained by flotation of polymetallic ore from the Rudnik deposit in Serbia. X-ray diffraction (XRD), qualitative and quantitative mineralogical, scanning electron microscopy (SEM/EDX), and chemical analyses were used to characterize the polymetallic concentrate and leach residue. The polymetallic concentrate contained chalcopyrite, galena, sphalerite, pyrrhotite, and quartz. The total content of sulfide minerals was 69.5%, and the occurrence of free sulfide mineral grains was about 60.9%. The comprehensive thermodynamic analysis was done by HSC Chemistry (R) package 9.9.2.3 to determine optimal experimental leaching conditions. Chalcopyrite, sphalerite, and pyrrhotite oxidized during leaching, and dissolution occurred. The oxidized galena remains in the solid residual as insoluble anglesite. Also, elemental sulfur and unleached minerals of copper, zinc, and iron were found in the leach residues. It was found that the structural assembly of sulfide minerals in the leach residue is very favorable and that undissolved sulfide grains are primarily present in free form. Accordingly, there was no reason to reduce the leaching rate with time. The presence of elemental sulfur and anglesite formed in the leaching process and precipitated on the surface of mineral grains was confirmed by XRD, quantitative and qualitative mineralogical analysis, and SEM/EDX.
PB  - Pleiades Publishing Inc, New York
T2  - Russian Journal of Non-Ferrous Metals
T1  - Modification of Structural-Textural Properties of Sulfide Minerals at Polymetallic Concentrate Leaching with Sulfuric Acid and Hydrogen Peroxide Solutions
EP  - 472
IS  - 5
SP  - 457
VL  - 63
DO  - 10.3103/S1067821222050091
UR  - conv_954
ER  - 

@article{
author = "Sokić, Miroslav and Stojanović, Jovica and Marković, Branislav and Kamberović, Željko and Gajić, Nataša and Radosavljević-Mihajlović, Ana and Milojkov, Dušan",
year = "2022",
abstract = "This paper examines the effects of structural-textural characteristics of sulfide minerals on their leaching from polymetallic concentrates with sulfuric acid and hydrogen peroxide solutions. The polymetallic concentrate was obtained by flotation of polymetallic ore from the Rudnik deposit in Serbia. X-ray diffraction (XRD), qualitative and quantitative mineralogical, scanning electron microscopy (SEM/EDX), and chemical analyses were used to characterize the polymetallic concentrate and leach residue. The polymetallic concentrate contained chalcopyrite, galena, sphalerite, pyrrhotite, and quartz. The total content of sulfide minerals was 69.5%, and the occurrence of free sulfide mineral grains was about 60.9%. The comprehensive thermodynamic analysis was done by HSC Chemistry (R) package 9.9.2.3 to determine optimal experimental leaching conditions. Chalcopyrite, sphalerite, and pyrrhotite oxidized during leaching, and dissolution occurred. The oxidized galena remains in the solid residual as insoluble anglesite. Also, elemental sulfur and unleached minerals of copper, zinc, and iron were found in the leach residues. It was found that the structural assembly of sulfide minerals in the leach residue is very favorable and that undissolved sulfide grains are primarily present in free form. Accordingly, there was no reason to reduce the leaching rate with time. The presence of elemental sulfur and anglesite formed in the leaching process and precipitated on the surface of mineral grains was confirmed by XRD, quantitative and qualitative mineralogical analysis, and SEM/EDX.",
publisher = "Pleiades Publishing Inc, New York",
journal = "Russian Journal of Non-Ferrous Metals",
title = "Modification of Structural-Textural Properties of Sulfide Minerals at Polymetallic Concentrate Leaching with Sulfuric Acid and Hydrogen Peroxide Solutions",
pages = "472-457",
number = "5",
volume = "63",
doi = "10.3103/S1067821222050091",
url = "conv_954"
}

Sokić, M., Stojanović, J., Marković, B., Kamberović, Ž., Gajić, N., Radosavljević-Mihajlović, A.,& Milojkov, D.. (2022). Modification of Structural-Textural Properties of Sulfide Minerals at Polymetallic Concentrate Leaching with Sulfuric Acid and Hydrogen Peroxide Solutions. in Russian Journal of Non-Ferrous Metals
Pleiades Publishing Inc, New York., 63(5), 457-472.
https://doi.org/10.3103/S1067821222050091
conv_954

Sokić M, Stojanović J, Marković B, Kamberović Ž, Gajić N, Radosavljević-Mihajlović A, Milojkov D. Modification of Structural-Textural Properties of Sulfide Minerals at Polymetallic Concentrate Leaching with Sulfuric Acid and Hydrogen Peroxide Solutions. in Russian Journal of Non-Ferrous Metals. 2022;63(5):457-472.
doi:10.3103/S1067821222050091
conv_954 .

Sokić, Miroslav, Stojanović, Jovica, Marković, Branislav, Kamberović, Željko, Gajić, Nataša, Radosavljević-Mihajlović, Ana, Milojkov, Dušan, "Modification of Structural-Textural Properties of Sulfide Minerals at Polymetallic Concentrate Leaching with Sulfuric Acid and Hydrogen Peroxide Solutions" in Russian Journal of Non-Ferrous Metals, 63, no. 5 (2022):457-472,
https://doi.org/10.3103/S1067821222050091 .,
conv_954 .

TY  - JOUR
AU  - Kamberović, Željko
AU  - Gajić, Nataša
AU  - Korać, Marija
AU  - Jevtić, Sanja
AU  - Sokić, Miroslav
AU  - Stojanović, Jovica
PY  - 2021
UR  - https://ritnms.itnms.ac.rs/handle/123456789/595
AB  - By-products from zinc hydrometallurgy are classified as hazardous waste with strong leaching toxicities. Even though numerous research papers are dedicated to valorizing valuable metals in it, the primary management route is still disposal or partial reuse, such as the Waelz process. Presented experimental research investigates possibilities of sulfidization and further processing as a technologically sustainable route for valuable metals valorization from non-standard jarosite-PbAg sludge. The comprehensive thermodynamic analysis was done by HSC Chemistry(R), through optimizing process parameters, i.e., temperature, sulfur addition, and selection of possible additives. Technological possibility of magnetic separation, flotation, and smelting of sulfidized material was also investigated; the results were below the values that allow practical application, due to the obtained texture of sulfidized jarosite, which does not allow the liberation of minerals. Smelting tests were performed on sulfidized jarosite with sulfur and without and with carbon as additive. By smelting sulfidized jarosite-PbAg sludge with added carbon in sulfidization stage at 1375 degrees C, obtained products were matte, slag, raw lead, and dust in which base, critical, and slag forming components were valorized. Valuable metals were concentrated in smelting products so as to enable further processing, which also could be interesting in the case of treatment of complex, polymetallic, and refractory primary materials, which represent a significant contribution to the circular economy.
PB  - MDPI, Basel
T2  - Minerals
T1  - Technologically Sustainable Route for Metals Valorization from Jarosite-PbAg Sludge
IS  - 3
VL  - 11
DO  - 10.3390/min11030255
UR  - conv_904
ER  - 

@article{
author = "Kamberović, Željko and Gajić, Nataša and Korać, Marija and Jevtić, Sanja and Sokić, Miroslav and Stojanović, Jovica",
year = "2021",
abstract = "By-products from zinc hydrometallurgy are classified as hazardous waste with strong leaching toxicities. Even though numerous research papers are dedicated to valorizing valuable metals in it, the primary management route is still disposal or partial reuse, such as the Waelz process. Presented experimental research investigates possibilities of sulfidization and further processing as a technologically sustainable route for valuable metals valorization from non-standard jarosite-PbAg sludge. The comprehensive thermodynamic analysis was done by HSC Chemistry(R), through optimizing process parameters, i.e., temperature, sulfur addition, and selection of possible additives. Technological possibility of magnetic separation, flotation, and smelting of sulfidized material was also investigated; the results were below the values that allow practical application, due to the obtained texture of sulfidized jarosite, which does not allow the liberation of minerals. Smelting tests were performed on sulfidized jarosite with sulfur and without and with carbon as additive. By smelting sulfidized jarosite-PbAg sludge with added carbon in sulfidization stage at 1375 degrees C, obtained products were matte, slag, raw lead, and dust in which base, critical, and slag forming components were valorized. Valuable metals were concentrated in smelting products so as to enable further processing, which also could be interesting in the case of treatment of complex, polymetallic, and refractory primary materials, which represent a significant contribution to the circular economy.",
publisher = "MDPI, Basel",
journal = "Minerals",
title = "Technologically Sustainable Route for Metals Valorization from Jarosite-PbAg Sludge",
number = "3",
volume = "11",
doi = "10.3390/min11030255",
url = "conv_904"
}

Kamberović, Ž., Gajić, N., Korać, M., Jevtić, S., Sokić, M.,& Stojanović, J.. (2021). Technologically Sustainable Route for Metals Valorization from Jarosite-PbAg Sludge. in Minerals
MDPI, Basel., 11(3).
https://doi.org/10.3390/min11030255
conv_904

Kamberović Ž, Gajić N, Korać M, Jevtić S, Sokić M, Stojanović J. Technologically Sustainable Route for Metals Valorization from Jarosite-PbAg Sludge. in Minerals. 2021;11(3).
doi:10.3390/min11030255
conv_904 .

Kamberović, Željko, Gajić, Nataša, Korać, Marija, Jevtić, Sanja, Sokić, Miroslav, Stojanović, Jovica, "Technologically Sustainable Route for Metals Valorization from Jarosite-PbAg Sludge" in Minerals, 11, no. 3 (2021),
https://doi.org/10.3390/min11030255 .,
conv_904 .

TY  - JOUR
AU  - Nikolić, Vesna
AU  - Kamberović, Željko
AU  - Andić, Zoran
AU  - Korać, Marija
AU  - Sokić, Miroslav
AU  - Gajić, Nataša
AU  - Jovanović, Nikola
PY  - 2015
UR  - https://ritnms.itnms.ac.rs/handle/123456789/356
AB  - The goal of this research was to examine exploitation properties of Ni-Pd/Al2O3 catalyst supported on alpha-Al2O3 based foam in the dry methane reforming. The catalyst was prepared by using aerosol method. Chloride precursors for Ni and Pd were reduced by hydrogen at low temperature of 533 K, without previous calcination. The reforming experiment was performed for 3 h, with standing time of 1 h for each of the following temperatures: 873, 973 and 1023 K. Conclusions on selectivity, catalytic activity and stability were made on the basis of CO and H-2 yields.
PB  - Savez inženjera metalurgije Srbije, Beograd
T2  - Metallurgical & Materials Engineering
T1  - Exploitation properties of ni-pd/al2o3 catalyst supported on ceramic foam
EP  - 282
IS  - 4
SP  - 277
VL  - 21
DO  - 10.30544/74
UR  - conv_485
ER  - 

@article{
author = "Nikolić, Vesna and Kamberović, Željko and Andić, Zoran and Korać, Marija and Sokić, Miroslav and Gajić, Nataša and Jovanović, Nikola",
year = "2015",
abstract = "The goal of this research was to examine exploitation properties of Ni-Pd/Al2O3 catalyst supported on alpha-Al2O3 based foam in the dry methane reforming. The catalyst was prepared by using aerosol method. Chloride precursors for Ni and Pd were reduced by hydrogen at low temperature of 533 K, without previous calcination. The reforming experiment was performed for 3 h, with standing time of 1 h for each of the following temperatures: 873, 973 and 1023 K. Conclusions on selectivity, catalytic activity and stability were made on the basis of CO and H-2 yields.",
publisher = "Savez inženjera metalurgije Srbije, Beograd",
journal = "Metallurgical & Materials Engineering",
title = "Exploitation properties of ni-pd/al2o3 catalyst supported on ceramic foam",
pages = "282-277",
number = "4",
volume = "21",
doi = "10.30544/74",
url = "conv_485"
}

Nikolić, V., Kamberović, Ž., Andić, Z., Korać, M., Sokić, M., Gajić, N.,& Jovanović, N.. (2015). Exploitation properties of ni-pd/al2o3 catalyst supported on ceramic foam. in Metallurgical & Materials Engineering
Savez inženjera metalurgije Srbije, Beograd., 21(4), 277-282.
https://doi.org/10.30544/74
conv_485

Nikolić V, Kamberović Ž, Andić Z, Korać M, Sokić M, Gajić N, Jovanović N. Exploitation properties of ni-pd/al2o3 catalyst supported on ceramic foam. in Metallurgical & Materials Engineering. 2015;21(4):277-282.
doi:10.30544/74
conv_485 .

Nikolić, Vesna, Kamberović, Željko, Andić, Zoran, Korać, Marija, Sokić, Miroslav, Gajić, Nataša, Jovanović, Nikola, "Exploitation properties of ni-pd/al2o3 catalyst supported on ceramic foam" in Metallurgical & Materials Engineering, 21, no. 4 (2015):277-282,
https://doi.org/10.30544/74 .,
conv_485 .