TY  - JOUR
AU  - Kamberović, Željko
AU  - Gajić, Nataša
AU  - Korać, Marija
AU  - Jevtić, Sanja
AU  - Sokić, Miroslav
AU  - Stojanovic, Jovica
PY  - 2021
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4900
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.
T2  - Minerals
T1  - Technologically Sustainable Route for Metals Valorization from Jarosite-PbAg Sludge
IS  - 3
VL  - 11
DO  - 10.3390/min11030255
ER  - 

@article{
author = "Kamberović, Željko and Gajić, Nataša and Korać, Marija and Jevtić, Sanja and Sokić, Miroslav and Stojanovic, 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.",
journal = "Minerals",
title = "Technologically Sustainable Route for Metals Valorization from Jarosite-PbAg Sludge",
number = "3",
volume = "11",
doi = "10.3390/min11030255"
}

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

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

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

TY  - JOUR
AU  - Stevanović, Milena
AU  - Đošić, Marija
AU  - Janković, Ana
AU  - Kojić, Vesna
AU  - Stojanović, Jovica
AU  - Grujić, Svetlana
AU  - Matić-Bujagić, Ivana
AU  - Rhee, Kyong Yop
AU  - Mišković-Stanković, Vesna
PY  - 2021
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4839
AB  - This paper describes a promising electrophoretic deposition (EPD) approach for developing composite coatings based on chitosan with the additional components of hydroxyapatite, graphene, and gentamicin on titanium substrate. Bioactive properties were investigated in vitro by immersing the coatings in simulated body fluid (SBF) at 37 degrees C. The newly formed biomimetic layer on the top of the deposited chitosan-based coatings on Ti was confirmed by X-ray diffraction, Fourier transform infrared spectroscopy, field emission scanning electron microscopy and electrochemical measurements, while coatings' bioactivity was proved by alkaline phosphatase activity assay in MRC-5 and L929 tested cell lines. The biocompatibility towards MRC-5 and L929 cell lines was investigated by dye exclusion test (DET) implying the non-cytotoxic effect of coatings. Gentamicin release studies were monitored during 21-day by high-performance liquid chromatography coupled with mass spectrometry, indicating rapid release of gentamicin (approximate to 40%) in the first 48 h and more than 60% after 14 days.
PB  - Elsevier B.V.
T2  - Journal of Materials Research and Technology
T1  - The chitosan-based bioactive composite coating on titanium
EP  - 4474
SP  - 4461
VL  - 15
DO  - 10.1016/j.jmrt.2021.10.072
ER  - 

@article{
author = "Stevanović, Milena and Đošić, Marija and Janković, Ana and Kojić, Vesna and Stojanović, Jovica and Grujić, Svetlana and Matić-Bujagić, Ivana and Rhee, Kyong Yop and Mišković-Stanković, Vesna",
year = "2021",
abstract = "This paper describes a promising electrophoretic deposition (EPD) approach for developing composite coatings based on chitosan with the additional components of hydroxyapatite, graphene, and gentamicin on titanium substrate. Bioactive properties were investigated in vitro by immersing the coatings in simulated body fluid (SBF) at 37 degrees C. The newly formed biomimetic layer on the top of the deposited chitosan-based coatings on Ti was confirmed by X-ray diffraction, Fourier transform infrared spectroscopy, field emission scanning electron microscopy and electrochemical measurements, while coatings' bioactivity was proved by alkaline phosphatase activity assay in MRC-5 and L929 tested cell lines. The biocompatibility towards MRC-5 and L929 cell lines was investigated by dye exclusion test (DET) implying the non-cytotoxic effect of coatings. Gentamicin release studies were monitored during 21-day by high-performance liquid chromatography coupled with mass spectrometry, indicating rapid release of gentamicin (approximate to 40%) in the first 48 h and more than 60% after 14 days.",
publisher = "Elsevier B.V.",
journal = "Journal of Materials Research and Technology",
title = "The chitosan-based bioactive composite coating on titanium",
pages = "4474-4461",
volume = "15",
doi = "10.1016/j.jmrt.2021.10.072"
}

Stevanović, M., Đošić, M., Janković, A., Kojić, V., Stojanović, J., Grujić, S., Matić-Bujagić, I., Rhee, K. Y.,& Mišković-Stanković, V.. (2021). The chitosan-based bioactive composite coating on titanium. in Journal of Materials Research and Technology
Elsevier B.V.., 15, 4461-4474.
https://doi.org/10.1016/j.jmrt.2021.10.072

Stevanović M, Đošić M, Janković A, Kojić V, Stojanović J, Grujić S, Matić-Bujagić I, Rhee KY, Mišković-Stanković V. The chitosan-based bioactive composite coating on titanium. in Journal of Materials Research and Technology. 2021;15:4461-4474.
doi:10.1016/j.jmrt.2021.10.072 .

Stevanović, Milena, Đošić, Marija, Janković, Ana, Kojić, Vesna, Stojanović, Jovica, Grujić, Svetlana, Matić-Bujagić, Ivana, Rhee, Kyong Yop, Mišković-Stanković, Vesna, "The chitosan-based bioactive composite coating on titanium" in Journal of Materials Research and Technology, 15 (2021):4461-4474,
https://doi.org/10.1016/j.jmrt.2021.10.072 . .

TY  - JOUR
AU  - Terzic, Anja
AU  - Dojčinović, Marina
AU  - Milicic, Ljiljana
AU  - Stojanovic, Jovica
AU  - Radojevic, Zagorka
PY  - 2021
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4958
AB  - Micro-silica is a highly efficient mineral additive whose role is reflected in improvements of microstructure packing, strength and durability of non-shaped composite building materials such as concrete and mortar. A comparative study of performances of rendering mortars with different quantities of micro silica was conducted. The experimental program included production of reference mortar based on Portland cement and quartz sand (CM) and three mortars with 5, 10, and 15 % addition of micro silica (SCM-5, SCM-10, and SCM-15). The effect that micro silica addition has on the thermal behavior and mechanical properties of mortars was discussed. Hydration mechanisms and thermally induced reactions were studied at temperatures ranging from ambient to 1100 degrees C by differential thermal analysis. The results were supported by X-ray diffraction analysis. The cementing efficiency of micro silica was assessed by cavitation erosion test. The changes in the morphology of mortar samples prior and upon cavitation testing were monitored by means of the scanning electron microscope imagining. It was found that 5 % of superfine micro silica (SCM-5 mortar) has positive effects on mechanical strengths (15 % increase in compressive strength) due to microstructure densification arising from the successive filling of voids by the micro silica. Addition of micro silica also improved the cavitation erosion resistance in comparison with reference cement mortar (SCM-5 showed cavitation velocity as low as 0.09 mg/min). This qualifies mortars with micro silica addition as building materials which can be safely employed in potential hydro-demolition environment.
T2  - Science of Sintering
T1  - Cavitation Properties of Rendering Mortars with Micro Silica Addition
EP  - 459
IS  - 4
SP  - 445
VL  - 53
DO  - 10.2298/SOS2104445T
ER  - 

@article{
author = "Terzic, Anja and Dojčinović, Marina and Milicic, Ljiljana and Stojanovic, Jovica and Radojevic, Zagorka",
year = "2021",
abstract = "Micro-silica is a highly efficient mineral additive whose role is reflected in improvements of microstructure packing, strength and durability of non-shaped composite building materials such as concrete and mortar. A comparative study of performances of rendering mortars with different quantities of micro silica was conducted. The experimental program included production of reference mortar based on Portland cement and quartz sand (CM) and three mortars with 5, 10, and 15 % addition of micro silica (SCM-5, SCM-10, and SCM-15). The effect that micro silica addition has on the thermal behavior and mechanical properties of mortars was discussed. Hydration mechanisms and thermally induced reactions were studied at temperatures ranging from ambient to 1100 degrees C by differential thermal analysis. The results were supported by X-ray diffraction analysis. The cementing efficiency of micro silica was assessed by cavitation erosion test. The changes in the morphology of mortar samples prior and upon cavitation testing were monitored by means of the scanning electron microscope imagining. It was found that 5 % of superfine micro silica (SCM-5 mortar) has positive effects on mechanical strengths (15 % increase in compressive strength) due to microstructure densification arising from the successive filling of voids by the micro silica. Addition of micro silica also improved the cavitation erosion resistance in comparison with reference cement mortar (SCM-5 showed cavitation velocity as low as 0.09 mg/min). This qualifies mortars with micro silica addition as building materials which can be safely employed in potential hydro-demolition environment.",
journal = "Science of Sintering",
title = "Cavitation Properties of Rendering Mortars with Micro Silica Addition",
pages = "459-445",
number = "4",
volume = "53",
doi = "10.2298/SOS2104445T"
}

Terzic, A., Dojčinović, M., Milicic, L., Stojanovic, J.,& Radojevic, Z.. (2021). Cavitation Properties of Rendering Mortars with Micro Silica Addition. in Science of Sintering, 53(4), 445-459.
https://doi.org/10.2298/SOS2104445T

Terzic A, Dojčinović M, Milicic L, Stojanovic J, Radojevic Z. Cavitation Properties of Rendering Mortars with Micro Silica Addition. in Science of Sintering. 2021;53(4):445-459.
doi:10.2298/SOS2104445T .

Terzic, Anja, Dojčinović, Marina, Milicic, Ljiljana, Stojanovic, Jovica, Radojevic, Zagorka, "Cavitation Properties of Rendering Mortars with Micro Silica Addition" in Science of Sintering, 53, no. 4 (2021):445-459,
https://doi.org/10.2298/SOS2104445T . .