TY  - JOUR
AU  - Živković, Dragana
AU  - Balanović, Ljubiša
AU  - Mitovski, Aleksandra
AU  - Talijan, Nadežda
AU  - Štrbac, Nada
AU  - Sokić, Miroslav
AU  - Manasijević, Dragan
AU  - Minić, Duško
AU  - Ćosović, Vladan
PY  - 2016
UR  - https://ritnms.itnms.ac.rs/handle/123456789/386
AB  - Uredništvo časopisa 'Reciklaža i održivi razvoj' je u dogovoru sa autorskim timom preglednog rada pod nazivom ' EKološki rizici i reciklaža nanomaterijala - aktuelna pitanja ' (D. Živković, Lj. Balanović, A. Mitovski, N. Talijan, N. Štrbac, M. Sokić, D. Manasijević, D. Minić, V. Ćosović), koji je publikovan u ovom časopisu vol.7 iz 2014. godine (str.1-8), donelo odluku da se zbog uočenog ozbiljnog previda (na osnovu provere CEON-a), koji se ogleda u neadekvatnom citiranju jedne reference, odnosno izostavljanju reference iz koje su korišćeni pojedini tekstualni navodi, kao i dupliranja pojedinih referenci, izvrši neophodna ispravka onih delova rada u kome pomenuti referentni izvor nije adekvatno naveden, kao i ispravke u listi referenci, a u skladu sa propisanom procedurom.
AB  - Editorial board of the 'Recycling and Sustainable Development' Journal in agreement with the authors of the article titled 'Nanomaterials environmental risks and recycling - actual issues' (D. Zivkovic, Lj. Balanović, A. Mitovski, N. Talijan, N. Strbac , M. Sokić, D. Manasijević, D. Minić, V. Ćosović), which was published in this journal vol. 7 in 2014 (p. 1-8), made the decision to do correction of article because of a perceived serious oversights (based on check out by CEON). Oversight is reflected in inadequate citing a reference, or omission of reference from which the text used by individual states, as well as the duplication of certain references. The necessary correction refers to the parts of the article which reference source is not adequately specified and updates the list of references, in accordance with prescribed procedure.
PB  - Univerzitet u Beogradu - Tehnički fakultet u Boru, Beograd
T2  - Recycling and Sustainable Development
T1  - Ispravka: Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja (2014, vol. 7, p. 1)
T1  - Correction: Nanomaterials environmental risks and recycling: Actual issues (2014, vol. 7, p. 1)
EP  - 4
IS  - 1
SP  - 1
VL  - 9
DO  - 10.5937/ror1601001Z
UR  - conv_403
ER  - 

@article{
author = "Živković, Dragana and Balanović, Ljubiša and Mitovski, Aleksandra and Talijan, Nadežda and Štrbac, Nada and Sokić, Miroslav and Manasijević, Dragan and Minić, Duško and Ćosović, Vladan",
year = "2016",
abstract = "Uredništvo časopisa 'Reciklaža i održivi razvoj' je u dogovoru sa autorskim timom preglednog rada pod nazivom ' EKološki rizici i reciklaža nanomaterijala - aktuelna pitanja ' (D. Živković, Lj. Balanović, A. Mitovski, N. Talijan, N. Štrbac, M. Sokić, D. Manasijević, D. Minić, V. Ćosović), koji je publikovan u ovom časopisu vol.7 iz 2014. godine (str.1-8), donelo odluku da se zbog uočenog ozbiljnog previda (na osnovu provere CEON-a), koji se ogleda u neadekvatnom citiranju jedne reference, odnosno izostavljanju reference iz koje su korišćeni pojedini tekstualni navodi, kao i dupliranja pojedinih referenci, izvrši neophodna ispravka onih delova rada u kome pomenuti referentni izvor nije adekvatno naveden, kao i ispravke u listi referenci, a u skladu sa propisanom procedurom., Editorial board of the 'Recycling and Sustainable Development' Journal in agreement with the authors of the article titled 'Nanomaterials environmental risks and recycling - actual issues' (D. Zivkovic, Lj. Balanović, A. Mitovski, N. Talijan, N. Strbac , M. Sokić, D. Manasijević, D. Minić, V. Ćosović), which was published in this journal vol. 7 in 2014 (p. 1-8), made the decision to do correction of article because of a perceived serious oversights (based on check out by CEON). Oversight is reflected in inadequate citing a reference, or omission of reference from which the text used by individual states, as well as the duplication of certain references. The necessary correction refers to the parts of the article which reference source is not adequately specified and updates the list of references, in accordance with prescribed procedure.",
publisher = "Univerzitet u Beogradu - Tehnički fakultet u Boru, Beograd",
journal = "Recycling and Sustainable Development",
title = "Ispravka: Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja (2014, vol. 7, p. 1), Correction: Nanomaterials environmental risks and recycling: Actual issues (2014, vol. 7, p. 1)",
pages = "4-1",
number = "1",
volume = "9",
doi = "10.5937/ror1601001Z",
url = "conv_403"
}

Živković, D., Balanović, L., Mitovski, A., Talijan, N., Štrbac, N., Sokić, M., Manasijević, D., Minić, D.,& Ćosović, V.. (2016). Ispravka: Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja (2014, vol. 7, p. 1). in Recycling and Sustainable Development
Univerzitet u Beogradu - Tehnički fakultet u Boru, Beograd., 9(1), 1-4.
https://doi.org/10.5937/ror1601001Z
conv_403

Živković D, Balanović L, Mitovski A, Talijan N, Štrbac N, Sokić M, Manasijević D, Minić D, Ćosović V. Ispravka: Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja (2014, vol. 7, p. 1). in Recycling and Sustainable Development. 2016;9(1):1-4.
doi:10.5937/ror1601001Z
conv_403 .

Živković, Dragana, Balanović, Ljubiša, Mitovski, Aleksandra, Talijan, Nadežda, Štrbac, Nada, Sokić, Miroslav, Manasijević, Dragan, Minić, Duško, Ćosović, Vladan, "Ispravka: Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja (2014, vol. 7, p. 1)" in Recycling and Sustainable Development, 9, no. 1 (2016):1-4,
https://doi.org/10.5937/ror1601001Z .,
conv_403 .

TY  - JOUR
AU  - Mitovski, Aleksandra
AU  - Štrbac, Nada
AU  - Manasijević, Dragan
AU  - Sokić, Miroslav
AU  - Daković, Aleksandra
AU  - Živković, D.
AU  - Balanović, Ljubiša
PY  - 2015
UR  - https://ritnms.itnms.ac.rs/handle/123456789/359
AB  - The paper presents the results of experimental investigation of the chalcopyrite-pyrite concentrate oxidation in the air. Characterisation of the initial sample and oxidation products was done by ICP-AES, XRD, EDXRF methods. Phase stability diagrams were constructed for Cu-Fe-S-O system at 25,450,650 and 900 degrees C. Equilibrium composition of the charge for the optimal oxidation process was calculated. DTA-TG analysis was used for monitoring the oxidation process. Kinetic parameters in non-isothermal conditions were determined, based on Kissinger and Ozawa methods. Values of activation energies showed that all stages of the oxidation process occur in the kinetic field.
PB  - Faculty of Metallurgy
T2  - Metalurgija
T1  - Thermal analysis and kinetics of the chalcopyrite-pyrite concentrate oxidation process
EP  - 314
IS  - 2
SP  - 311
VL  - 54
UR  - conv_1039
ER  - 

@article{
author = "Mitovski, Aleksandra and Štrbac, Nada and Manasijević, Dragan and Sokić, Miroslav and Daković, Aleksandra and Živković, D. and Balanović, Ljubiša",
year = "2015",
abstract = "The paper presents the results of experimental investigation of the chalcopyrite-pyrite concentrate oxidation in the air. Characterisation of the initial sample and oxidation products was done by ICP-AES, XRD, EDXRF methods. Phase stability diagrams were constructed for Cu-Fe-S-O system at 25,450,650 and 900 degrees C. Equilibrium composition of the charge for the optimal oxidation process was calculated. DTA-TG analysis was used for monitoring the oxidation process. Kinetic parameters in non-isothermal conditions were determined, based on Kissinger and Ozawa methods. Values of activation energies showed that all stages of the oxidation process occur in the kinetic field.",
publisher = "Faculty of Metallurgy",
journal = "Metalurgija",
title = "Thermal analysis and kinetics of the chalcopyrite-pyrite concentrate oxidation process",
pages = "314-311",
number = "2",
volume = "54",
url = "conv_1039"
}

Mitovski, A., Štrbac, N., Manasijević, D., Sokić, M., Daković, A., Živković, D.,& Balanović, L.. (2015). Thermal analysis and kinetics of the chalcopyrite-pyrite concentrate oxidation process. in Metalurgija
Faculty of Metallurgy., 54(2), 311-314.
conv_1039

Mitovski A, Štrbac N, Manasijević D, Sokić M, Daković A, Živković D, Balanović L. Thermal analysis and kinetics of the chalcopyrite-pyrite concentrate oxidation process. in Metalurgija. 2015;54(2):311-314.
conv_1039 .

Mitovski, Aleksandra, Štrbac, Nada, Manasijević, Dragan, Sokić, Miroslav, Daković, Aleksandra, Živković, D., Balanović, Ljubiša, "Thermal analysis and kinetics of the chalcopyrite-pyrite concentrate oxidation process" in Metalurgija, 54, no. 2 (2015):311-314,
conv_1039 .

TY  - JOUR
AU  - Gomidzelović, Lidija
AU  - Pozega, Emina
AU  - Kostov, Ana
AU  - Vuković, Nikola
AU  - Krstić, Vesna
AU  - Živković, Dragana
AU  - Balanović, Ljubiša
PY  - 2015
UR  - https://ritnms.itnms.ac.rs/handle/123456789/353
AB  - The thermodynamic properties and the microstructure, hardness and electrical conductivity of shape memory alloys (SMAs) belonging to ternary Cu-Al-Zn system were studied by Muggianu model and experiment, respectively. The isothermal section of phase diagram at 293 K was calculated using Thermo-Calc software. Experiments were conducted by X-ray diffraction, light optic microscopy, scanning electron microscopy with energy dispersive X-ray spectrometry, hardness and electrical conductivity measurements. The calculated values of thermodynamic properties indicate that Cu shows good miscibility with Al and Zn in all investigated alloys. The microstructural analysis of samples reveals that the structure consists of large and polygonal grains.
PB  - Elsevier Science Bv, Amsterdam
T2  - Transactions of Nonferrous Metals Society of China
T1  - Thermodynamics and characterization of shape memory Cu-Al-Zn alloys
EP  - 2636
IS  - 8
SP  - 2630
VL  - 25
DO  - 10.1016/S1003-6326(15)63885-7
UR  - conv_737
ER  - 

@article{
author = "Gomidzelović, Lidija and Pozega, Emina and Kostov, Ana and Vuković, Nikola and Krstić, Vesna and Živković, Dragana and Balanović, Ljubiša",
year = "2015",
abstract = "The thermodynamic properties and the microstructure, hardness and electrical conductivity of shape memory alloys (SMAs) belonging to ternary Cu-Al-Zn system were studied by Muggianu model and experiment, respectively. The isothermal section of phase diagram at 293 K was calculated using Thermo-Calc software. Experiments were conducted by X-ray diffraction, light optic microscopy, scanning electron microscopy with energy dispersive X-ray spectrometry, hardness and electrical conductivity measurements. The calculated values of thermodynamic properties indicate that Cu shows good miscibility with Al and Zn in all investigated alloys. The microstructural analysis of samples reveals that the structure consists of large and polygonal grains.",
publisher = "Elsevier Science Bv, Amsterdam",
journal = "Transactions of Nonferrous Metals Society of China",
title = "Thermodynamics and characterization of shape memory Cu-Al-Zn alloys",
pages = "2636-2630",
number = "8",
volume = "25",
doi = "10.1016/S1003-6326(15)63885-7",
url = "conv_737"
}

Gomidzelović, L., Pozega, E., Kostov, A., Vuković, N., Krstić, V., Živković, D.,& Balanović, L.. (2015). Thermodynamics and characterization of shape memory Cu-Al-Zn alloys. in Transactions of Nonferrous Metals Society of China
Elsevier Science Bv, Amsterdam., 25(8), 2630-2636.
https://doi.org/10.1016/S1003-6326(15)63885-7
conv_737

Gomidzelović L, Pozega E, Kostov A, Vuković N, Krstić V, Živković D, Balanović L. Thermodynamics and characterization of shape memory Cu-Al-Zn alloys. in Transactions of Nonferrous Metals Society of China. 2015;25(8):2630-2636.
doi:10.1016/S1003-6326(15)63885-7
conv_737 .

Gomidzelović, Lidija, Pozega, Emina, Kostov, Ana, Vuković, Nikola, Krstić, Vesna, Živković, Dragana, Balanović, Ljubiša, "Thermodynamics and characterization of shape memory Cu-Al-Zn alloys" in Transactions of Nonferrous Metals Society of China, 25, no. 8 (2015):2630-2636,
https://doi.org/10.1016/S1003-6326(15)63885-7 .,
conv_737 .

TY  - JOUR
AU  - Živković, Dragana
AU  - Balanović, Ljubiša
AU  - Mitovski, Aleksandra
AU  - Talijan, Nadežda
AU  - Štrbac, Nada
AU  - Sokić, Miroslav
AU  - Manasijević, Dragan
AU  - Minić, Duško
AU  - Ćosović, Vladan
PY  - 2014
UR  - https://ritnms.itnms.ac.rs/handle/123456789/301
AB  - Nanotehnologije se smatraju pokretačkom snagom nove industrijske revolucije. Nanonauka je tokom poslednje decenije značajno evoluirala od nauke koja se isključivo razvijala u laboratorijskim uslovima, do njene aplikacije u primenjenim tehnologijama. Trenutno, nanomaterijali se koriste u širokom spektru komercijalnih proizvoda kao što su elektronske komponente, sportska oprema, kreme za sunčanje i u biomedicinske svrhe. Veličina nanočestica omogućava im snažnu interakciju sa biološkim strukturama, tako da nanočestice predstavljaju potencijalni rizik po životnu sredinu i zdravlje ljudi. Nanometar kao veličina takođe predstavlja problem za separaciju, reciklažu i ponovno korišćenje nanočestica. Dakle, proizvodnja nanomaterijala u industrijskim razmerama i njihova primena mogli bi imati značajan uticaj na zdravlje ljudi i životnu sredinu ili stvorili probleme pri reciklaži. Sveobuhvatni termin 'nanotehnologija' nije dovoljno precizan kada se radi o upravljanju rizicima. Procena mogućih rizika zavisi od razmatranja životnog ciklusa materijala koji se proizvodi, a koji uključuje razumevanje procesa i materijala koji se koriste u proizvodnji, verovatne interakcije između proizvoda i pojedinaca ili životne sredine tokom proizvodnje nanomaterijala i njegovog životnog ciklusa, kao i metoda koje se koriste za njihovo konačno odlaganje. Sa stanovišta kontrole rizika, neophodno je identifikovati kritične faze, koje je neophodno detaljno istražiti. Pregled aktuelnih trendova ekoloških rizika i reciklaži nanomaterijala prezentovan je u ovom radu.
AB  - Nanotechnologies are being spoken of as the driving force behind a new industrial revolution. Nanoscience has matured significantly during the last decade as it has transitioned from bench top science to applied technology. Presently, nanomaterials are used in a wide variety of commercial products such as electronic components, sports equipment, sun creams and biomedical applications. The size of nanoparticles allows them to interact strongly with biological structures, so they present potential human and environmental health risk. Nanometer size presents also a problem for separation, recovery, and reuse of the particulate matter. Therefore, industrial-scale manufacturing and use of nanomaterials could have strong impact on human health and the environment or the problematic of nanomaterials recycling. The catch-all term ''nanotechnology' is not sufficiently precise for risk governance and risk management purposes. The estimation of possible risks depends on a consideration of the life cycle of the material being produced, which involves understanding the processes and materials used in manufacture, the likely interactions between the product and individuals or the environment during its manufacture and useful life, and the methods used in its eventual disposal. From a risk-control point of view it will be necessary to systematically identify those critical issues, which should be looked at in more detail. Brief review of actual trends in nanomaterials environmental risks and recycling is given in this paper.
PB  - Univerzitet u Beogradu - Tehnički fakultet u Boru, Beograd
T2  - Recycling and Sustainable Development
T1  - Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja
T1  - Nanomaterials environmental risks and recycling: Actual issues
EP  - 8
IS  - 1
SP  - 1
VL  - 7
DO  - 10.5937/ror1401001Z
UR  - conv_402
ER  - 

@article{
author = "Živković, Dragana and Balanović, Ljubiša and Mitovski, Aleksandra and Talijan, Nadežda and Štrbac, Nada and Sokić, Miroslav and Manasijević, Dragan and Minić, Duško and Ćosović, Vladan",
year = "2014",
abstract = "Nanotehnologije se smatraju pokretačkom snagom nove industrijske revolucije. Nanonauka je tokom poslednje decenije značajno evoluirala od nauke koja se isključivo razvijala u laboratorijskim uslovima, do njene aplikacije u primenjenim tehnologijama. Trenutno, nanomaterijali se koriste u širokom spektru komercijalnih proizvoda kao što su elektronske komponente, sportska oprema, kreme za sunčanje i u biomedicinske svrhe. Veličina nanočestica omogućava im snažnu interakciju sa biološkim strukturama, tako da nanočestice predstavljaju potencijalni rizik po životnu sredinu i zdravlje ljudi. Nanometar kao veličina takođe predstavlja problem za separaciju, reciklažu i ponovno korišćenje nanočestica. Dakle, proizvodnja nanomaterijala u industrijskim razmerama i njihova primena mogli bi imati značajan uticaj na zdravlje ljudi i životnu sredinu ili stvorili probleme pri reciklaži. Sveobuhvatni termin 'nanotehnologija' nije dovoljno precizan kada se radi o upravljanju rizicima. Procena mogućih rizika zavisi od razmatranja životnog ciklusa materijala koji se proizvodi, a koji uključuje razumevanje procesa i materijala koji se koriste u proizvodnji, verovatne interakcije između proizvoda i pojedinaca ili životne sredine tokom proizvodnje nanomaterijala i njegovog životnog ciklusa, kao i metoda koje se koriste za njihovo konačno odlaganje. Sa stanovišta kontrole rizika, neophodno je identifikovati kritične faze, koje je neophodno detaljno istražiti. Pregled aktuelnih trendova ekoloških rizika i reciklaži nanomaterijala prezentovan je u ovom radu., Nanotechnologies are being spoken of as the driving force behind a new industrial revolution. Nanoscience has matured significantly during the last decade as it has transitioned from bench top science to applied technology. Presently, nanomaterials are used in a wide variety of commercial products such as electronic components, sports equipment, sun creams and biomedical applications. The size of nanoparticles allows them to interact strongly with biological structures, so they present potential human and environmental health risk. Nanometer size presents also a problem for separation, recovery, and reuse of the particulate matter. Therefore, industrial-scale manufacturing and use of nanomaterials could have strong impact on human health and the environment or the problematic of nanomaterials recycling. The catch-all term ''nanotechnology' is not sufficiently precise for risk governance and risk management purposes. The estimation of possible risks depends on a consideration of the life cycle of the material being produced, which involves understanding the processes and materials used in manufacture, the likely interactions between the product and individuals or the environment during its manufacture and useful life, and the methods used in its eventual disposal. From a risk-control point of view it will be necessary to systematically identify those critical issues, which should be looked at in more detail. Brief review of actual trends in nanomaterials environmental risks and recycling is given in this paper.",
publisher = "Univerzitet u Beogradu - Tehnički fakultet u Boru, Beograd",
journal = "Recycling and Sustainable Development",
title = "Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja, Nanomaterials environmental risks and recycling: Actual issues",
pages = "8-1",
number = "1",
volume = "7",
doi = "10.5937/ror1401001Z",
url = "conv_402"
}

Živković, D., Balanović, L., Mitovski, A., Talijan, N., Štrbac, N., Sokić, M., Manasijević, D., Minić, D.,& Ćosović, V.. (2014). Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja. in Recycling and Sustainable Development
Univerzitet u Beogradu - Tehnički fakultet u Boru, Beograd., 7(1), 1-8.
https://doi.org/10.5937/ror1401001Z
conv_402

Živković D, Balanović L, Mitovski A, Talijan N, Štrbac N, Sokić M, Manasijević D, Minić D, Ćosović V. Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja. in Recycling and Sustainable Development. 2014;7(1):1-8.
doi:10.5937/ror1401001Z
conv_402 .

Živković, Dragana, Balanović, Ljubiša, Mitovski, Aleksandra, Talijan, Nadežda, Štrbac, Nada, Sokić, Miroslav, Manasijević, Dragan, Minić, Duško, Ćosović, Vladan, "Ekološki rizici i reciklaža nanomaterijala - aktuelna pitanja" in Recycling and Sustainable Development, 7, no. 1 (2014):1-8,
https://doi.org/10.5937/ror1401001Z .,
conv_402 .

TY  - JOUR
AU  - Živković, D.
AU  - Sokić, Miroslav
AU  - Živković, Z.
AU  - Manasijević, Dragan
AU  - Balanović, Ljubiša
AU  - Štrbac, Nada
AU  - Ćosović, Vladan
AU  - Boyanov, B.
PY  - 2013
UR  - https://ritnms.itnms.ac.rs/handle/123456789/252
AB  - The results of thermal study and mechanism of the oxidation process of synthetic Ag2S in air are presented in this article based on the comparative analysis of DTA and XRD results, as well as by constructed phase stability diagrams (PSD) for the Ag-S-O system.
PB  - Springer, Dordrecht
T2  - Journal of Thermal Analysis and Calorimetry
T1  - Thermal study and mechanism of Ag2S oxidation in air
EP  - 1176
IS  - 2
SP  - 1173
VL  - 111
DO  - 10.1007/s10973-012-2300-z
UR  - conv_644
ER  - 

@article{
author = "Živković, D. and Sokić, Miroslav and Živković, Z. and Manasijević, Dragan and Balanović, Ljubiša and Štrbac, Nada and Ćosović, Vladan and Boyanov, B.",
year = "2013",
abstract = "The results of thermal study and mechanism of the oxidation process of synthetic Ag2S in air are presented in this article based on the comparative analysis of DTA and XRD results, as well as by constructed phase stability diagrams (PSD) for the Ag-S-O system.",
publisher = "Springer, Dordrecht",
journal = "Journal of Thermal Analysis and Calorimetry",
title = "Thermal study and mechanism of Ag2S oxidation in air",
pages = "1176-1173",
number = "2",
volume = "111",
doi = "10.1007/s10973-012-2300-z",
url = "conv_644"
}

Živković, D., Sokić, M., Živković, Z., Manasijević, D., Balanović, L., Štrbac, N., Ćosović, V.,& Boyanov, B.. (2013). Thermal study and mechanism of Ag2S oxidation in air. in Journal of Thermal Analysis and Calorimetry
Springer, Dordrecht., 111(2), 1173-1176.
https://doi.org/10.1007/s10973-012-2300-z
conv_644

Živković D, Sokić M, Živković Z, Manasijević D, Balanović L, Štrbac N, Ćosović V, Boyanov B. Thermal study and mechanism of Ag2S oxidation in air. in Journal of Thermal Analysis and Calorimetry. 2013;111(2):1173-1176.
doi:10.1007/s10973-012-2300-z
conv_644 .

Živković, D., Sokić, Miroslav, Živković, Z., Manasijević, Dragan, Balanović, Ljubiša, Štrbac, Nada, Ćosović, Vladan, Boyanov, B., "Thermal study and mechanism of Ag2S oxidation in air" in Journal of Thermal Analysis and Calorimetry, 111, no. 2 (2013):1173-1176,
https://doi.org/10.1007/s10973-012-2300-z .,
conv_644 .

TY  - JOUR
AU  - Mitovski, Aleksandra
AU  - Sokić, Miroslav
AU  - Štrbac, Nada
AU  - Živković, Dragana
AU  - Balanović, Ljubiša
PY  - 2012
UR  - https://ritnms.itnms.ac.rs/handle/123456789/220
AB  - Kontinuirani informatički razvoj za posledicu ima stalni rast u proizvodnji čvrstog otpada. Elektronski otpad je deo univerzuma zastarelih i / ili oštećenih uređaja i komponenata koje treba na kraju njihovog životnog ciklusa na ekološki ispravan način odložiti, odnosno što je ekološki prihvatljivije - reciklirati. U ovom radu razmatrani su različiti hemijski postupci - korišćeni ili predloženi - za dobijanje metala iz elektronskog otpada, dostupni u literaturi i njihove prednosti i nedostatci. Svi navedeni postupci uključuju sledeće procese: pirometalurgiju, hidrometalurgiju, elektrohemiju i biotehnologiju (poslednje spomenuti proces neće biti predmet razmatranja u ovom radu). Dalji razvoj postojećih tehnologija ponovnog dobijanja metala iz elektronskog otpada usmerava se ka razvoju procesa sa većom efikasnošću, strogoj kontroli efluenata i emisija, primeni netoksičnih reagenasa uz mogućnost njihove maksimalne reciklabilnosti, smanjenju utroška energije - na ekonomski i ekološki siguran način.
AB  - The continuous IT development has resulted in steady growth in solid waste production. Electronic scrap is a part of the universe of obsolete and/or defective equipment and components that need to be disposed or, ecologically more appropriate, to be recycled, at the end of their life cycle. This paper considers various chemical processes - used or proposed - for obtaining metals from electronic waste, available in the literature and their advantages and disadvantages. All listed procedures include following processes: pyrometallurgy, hydrometallurgy, electrochemistry and biotechnology (the last mentioned process will not be considered in this paper). Further development of recovering metals technologies from electronic waste is directed towards the process development with greater efficiency, strict control of effluents and emissions, implementation of non-toxic reagents, with the possibility of their maximum recyclability, reduced energy consumption - in an economically and environmentally safe manner.
PB  - Naučno-stručno društvo za zaštitu životne sredine Srbije - Ecologica, Beograd
T2  - Ecologica
T1  - Aktuelne metode dobijanja metala iz elektronskog otpada
T1  - Current methods for recovering metals from electronic waste
EP  - 36
IS  - 65
SP  - 30
VL  - 19
UR  - conv_248
ER  - 

@article{
author = "Mitovski, Aleksandra and Sokić, Miroslav and Štrbac, Nada and Živković, Dragana and Balanović, Ljubiša",
year = "2012",
abstract = "Kontinuirani informatički razvoj za posledicu ima stalni rast u proizvodnji čvrstog otpada. Elektronski otpad je deo univerzuma zastarelih i / ili oštećenih uređaja i komponenata koje treba na kraju njihovog životnog ciklusa na ekološki ispravan način odložiti, odnosno što je ekološki prihvatljivije - reciklirati. U ovom radu razmatrani su različiti hemijski postupci - korišćeni ili predloženi - za dobijanje metala iz elektronskog otpada, dostupni u literaturi i njihove prednosti i nedostatci. Svi navedeni postupci uključuju sledeće procese: pirometalurgiju, hidrometalurgiju, elektrohemiju i biotehnologiju (poslednje spomenuti proces neće biti predmet razmatranja u ovom radu). Dalji razvoj postojećih tehnologija ponovnog dobijanja metala iz elektronskog otpada usmerava se ka razvoju procesa sa većom efikasnošću, strogoj kontroli efluenata i emisija, primeni netoksičnih reagenasa uz mogućnost njihove maksimalne reciklabilnosti, smanjenju utroška energije - na ekonomski i ekološki siguran način., The continuous IT development has resulted in steady growth in solid waste production. Electronic scrap is a part of the universe of obsolete and/or defective equipment and components that need to be disposed or, ecologically more appropriate, to be recycled, at the end of their life cycle. This paper considers various chemical processes - used or proposed - for obtaining metals from electronic waste, available in the literature and their advantages and disadvantages. All listed procedures include following processes: pyrometallurgy, hydrometallurgy, electrochemistry and biotechnology (the last mentioned process will not be considered in this paper). Further development of recovering metals technologies from electronic waste is directed towards the process development with greater efficiency, strict control of effluents and emissions, implementation of non-toxic reagents, with the possibility of their maximum recyclability, reduced energy consumption - in an economically and environmentally safe manner.",
publisher = "Naučno-stručno društvo za zaštitu životne sredine Srbije - Ecologica, Beograd",
journal = "Ecologica",
title = "Aktuelne metode dobijanja metala iz elektronskog otpada, Current methods for recovering metals from electronic waste",
pages = "36-30",
number = "65",
volume = "19",
url = "conv_248"
}

Mitovski, A., Sokić, M., Štrbac, N., Živković, D.,& Balanović, L.. (2012). Aktuelne metode dobijanja metala iz elektronskog otpada. in Ecologica
Naučno-stručno društvo za zaštitu životne sredine Srbije - Ecologica, Beograd., 19(65), 30-36.
conv_248

Mitovski A, Sokić M, Štrbac N, Živković D, Balanović L. Aktuelne metode dobijanja metala iz elektronskog otpada. in Ecologica. 2012;19(65):30-36.
conv_248 .

Mitovski, Aleksandra, Sokić, Miroslav, Štrbac, Nada, Živković, Dragana, Balanović, Ljubiša, "Aktuelne metode dobijanja metala iz elektronskog otpada" in Ecologica, 19, no. 65 (2012):30-36,
conv_248 .