TY  - JOUR
AU  - Spasojević, Milica
AU  - Luković, Milentije
AU  - Arnaut, Suzana
AU  - Maričić, Ema
AU  - Spasojević, Miroslav
PY  - 2022
UR  - https://www.sciencedirect.com/science/article/pii/S0254058422002930?via%3Dihub
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/5140
AB  - A novel multiferroic composite material, composed of a mixture of nanocrystals of BaT1-xMexO3 and MeFe12O19 (Me = Zn and Mn) and an amorphous phases of BaTi1-xMexO3, MeFe12O19 and MeFe2O4, is synthetized. The composite material consisting of the mixture of nanocrystals of Fe2O3, ZnO and BaTiO3 embedded into the amorphous phase of MnCO3 is obtained by grinding the powder mixture of 17.0 wt% Fe2O3, 4.4 wt% MnCO3, 3.6 wt% ZnO and 75.0 wt% BaTiO3 for 20 min. The powders as-ground for 80 min and more are composed of the mixture of nanocrystals of Fe2O3 and BaTiO3 embedded in the amorphous phase of Fe2O3, ZnO, BaTiO3 and MnCO3. With increasing grinding time, formation of the composite with finer particles, a lower mean size of nanocrystals, higher content of the amorphous phase and higher magnetization is observed. The magnetization of the pressed samples increases with increasing grinding time. Grinding declines the amount of large weakly-ferromagnetic crystals of hematite, however it increases the quantity of paramagnetic small nanocrystals and the amorphous phase. The powder is thermostable up to 280 °C. Annealing above 280 °C results in the decrease in the magnetization of the cooled sample as a consequence of crystallization of the amorphous phase and enlargement of the size of nanocrystals. When sintering for 2 h at 1200 °C, the mixture of nanocrystals of BaTi1-xMexО3 and MeFe12O19 embedded into the amorphous matrix composed of BaTi1-xMexO3, MeFe12O19 and MeFe2О4 is formed. The sintered samples ground for longer periods of time are mainly composed of the amorphous phase and fine nanocrystals. Grinding of powders for less than 100 min results in the sintered samples with a granular structure, whereas the samples obtained from powders ground for more than 160 min are relatively compact. The magnetization of the sintered samples declines with increasing grinding time to 180 min due to transformation of nanocrystals into the amorphous phase. Further increase in grinding time from 180 to 240 min causes the increase in the magnetization, resulting from the effect of sintering. The magnetization of the sintered samples ground for more than 240 min declines with increasing grinding time, since the amount of the amorphous phase rapidly increases when grinding above 240 min. The samples sintered from the powders ground for 240 min show the compact structure and maximum magnetization.
PB  - Elsevier
T2  - Materials Chemistry and Physics
T1  - The properties of mechanically activated powders consisting of 17.0 wt% Fe2O3, 4.4 wt% MnCO3, 3.6 wt% ZnO and 75.0 wt% BaTiO3
VL  - 283
DO  - 10.1016/j.matchemphys.2022.125987
ER  - 

@article{
author = "Spasojević, Milica and Luković, Milentije and Arnaut, Suzana and Maričić, Ema and Spasojević, Miroslav",
year = "2022",
abstract = "A novel multiferroic composite material, composed of a mixture of nanocrystals of BaT1-xMexO3 and MeFe12O19 (Me = Zn and Mn) and an amorphous phases of BaTi1-xMexO3, MeFe12O19 and MeFe2O4, is synthetized. The composite material consisting of the mixture of nanocrystals of Fe2O3, ZnO and BaTiO3 embedded into the amorphous phase of MnCO3 is obtained by grinding the powder mixture of 17.0 wt% Fe2O3, 4.4 wt% MnCO3, 3.6 wt% ZnO and 75.0 wt% BaTiO3 for 20 min. The powders as-ground for 80 min and more are composed of the mixture of nanocrystals of Fe2O3 and BaTiO3 embedded in the amorphous phase of Fe2O3, ZnO, BaTiO3 and MnCO3. With increasing grinding time, formation of the composite with finer particles, a lower mean size of nanocrystals, higher content of the amorphous phase and higher magnetization is observed. The magnetization of the pressed samples increases with increasing grinding time. Grinding declines the amount of large weakly-ferromagnetic crystals of hematite, however it increases the quantity of paramagnetic small nanocrystals and the amorphous phase. The powder is thermostable up to 280 °C. Annealing above 280 °C results in the decrease in the magnetization of the cooled sample as a consequence of crystallization of the amorphous phase and enlargement of the size of nanocrystals. When sintering for 2 h at 1200 °C, the mixture of nanocrystals of BaTi1-xMexО3 and MeFe12O19 embedded into the amorphous matrix composed of BaTi1-xMexO3, MeFe12O19 and MeFe2О4 is formed. The sintered samples ground for longer periods of time are mainly composed of the amorphous phase and fine nanocrystals. Grinding of powders for less than 100 min results in the sintered samples with a granular structure, whereas the samples obtained from powders ground for more than 160 min are relatively compact. The magnetization of the sintered samples declines with increasing grinding time to 180 min due to transformation of nanocrystals into the amorphous phase. Further increase in grinding time from 180 to 240 min causes the increase in the magnetization, resulting from the effect of sintering. The magnetization of the sintered samples ground for more than 240 min declines with increasing grinding time, since the amount of the amorphous phase rapidly increases when grinding above 240 min. The samples sintered from the powders ground for 240 min show the compact structure and maximum magnetization.",
publisher = "Elsevier",
journal = "Materials Chemistry and Physics",
title = "The properties of mechanically activated powders consisting of 17.0 wt% Fe2O3, 4.4 wt% MnCO3, 3.6 wt% ZnO and 75.0 wt% BaTiO3",
volume = "283",
doi = "10.1016/j.matchemphys.2022.125987"
}

Spasojević, M., Luković, M., Arnaut, S., Maričić, E.,& Spasojević, M.. (2022). The properties of mechanically activated powders consisting of 17.0 wt% Fe2O3, 4.4 wt% MnCO3, 3.6 wt% ZnO and 75.0 wt% BaTiO3. in Materials Chemistry and Physics
Elsevier., 283.
https://doi.org/10.1016/j.matchemphys.2022.125987

Spasojević M, Luković M, Arnaut S, Maričić E, Spasojević M. The properties of mechanically activated powders consisting of 17.0 wt% Fe2O3, 4.4 wt% MnCO3, 3.6 wt% ZnO and 75.0 wt% BaTiO3. in Materials Chemistry and Physics. 2022;283.
doi:10.1016/j.matchemphys.2022.125987 .

Spasojević, Milica, Luković, Milentije, Arnaut, Suzana, Maričić, Ema, Spasojević, Miroslav, "The properties of mechanically activated powders consisting of 17.0 wt% Fe2O3, 4.4 wt% MnCO3, 3.6 wt% ZnO and 75.0 wt% BaTiO3" in Materials Chemistry and Physics, 283 (2022),
https://doi.org/10.1016/j.matchemphys.2022.125987 . .

TY  - JOUR
AU  - Lukić, Vladimir D.
AU  - Spasojević, Milica 
AU  - Luković, Milentije
AU  - Spasojević, Miroslav
AU  - Maričić, Aleksa
PY  - 2022
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/5621
AB  - Kinetics and mechanism of hydrogen adsorption in as-obtained and ground nuclear graphite
Wendelstein 7-X are examined. In the first time interval the adsorption process is determined
by dissociation of the hydrogen molecule, occurring at the outer surface and in open
micropores of nuclear graphite particles. However, in the second time interval, the slowest
step in the hydrogen adsorption is inter-granular and inter-crystallite diffusion in nanopores
of graphite. The X-ray analysis shows, that grinding of as-obtained nuclear graphite results in
finer particles with finer nanocrystals and larger density of opened pores and carbon reactive
sites. The capacity and rate of adsorption increase with comminution of nuclear graphite particles and adsorbed hydrogen does not sub stantially alter the microstructure of nuclear
graphite.
PB  - Belgrade : Vinča Institute of Nuclear Sciences
T2  - Nuclear Technology and Radiation Protection
T1  - Hydrogen Adsorption Process In Nanocrystalline Nuclear Graphite
VL  - 37
IS  - 1
SP  - 11
EP  - 17
DO  - 10.2298/NTRP2201011L
ER  - 

@article{
author = "Lukić, Vladimir D. and Spasojević, Milica  and Luković, Milentije and Spasojević, Miroslav and Maričić, Aleksa",
year = "2022",
abstract = "Kinetics and mechanism of hydrogen adsorption in as-obtained and ground nuclear graphite
Wendelstein 7-X are examined. In the first time interval the adsorption process is determined
by dissociation of the hydrogen molecule, occurring at the outer surface and in open
micropores of nuclear graphite particles. However, in the second time interval, the slowest
step in the hydrogen adsorption is inter-granular and inter-crystallite diffusion in nanopores
of graphite. The X-ray analysis shows, that grinding of as-obtained nuclear graphite results in
finer particles with finer nanocrystals and larger density of opened pores and carbon reactive
sites. The capacity and rate of adsorption increase with comminution of nuclear graphite particles and adsorbed hydrogen does not sub stantially alter the microstructure of nuclear
graphite.",
publisher = "Belgrade : Vinča Institute of Nuclear Sciences",
journal = "Nuclear Technology and Radiation Protection",
title = "Hydrogen Adsorption Process In Nanocrystalline Nuclear Graphite",
volume = "37",
number = "1",
pages = "11-17",
doi = "10.2298/NTRP2201011L"
}

Lukić, V. D., Spasojević, M., Luković, M., Spasojević, M.,& Maričić, A.. (2022). Hydrogen Adsorption Process In Nanocrystalline Nuclear Graphite. in Nuclear Technology and Radiation Protection
Belgrade : Vinča Institute of Nuclear Sciences., 37(1), 11-17.
https://doi.org/10.2298/NTRP2201011L

Lukić VD, Spasojević M, Luković M, Spasojević M, Maričić A. Hydrogen Adsorption Process In Nanocrystalline Nuclear Graphite. in Nuclear Technology and Radiation Protection. 2022;37(1):11-17.
doi:10.2298/NTRP2201011L .

Lukić, Vladimir D., Spasojević, Milica , Luković, Milentije, Spasojević, Miroslav, Maričić, Aleksa, "Hydrogen Adsorption Process In Nanocrystalline Nuclear Graphite" in Nuclear Technology and Radiation Protection, 37, no. 1 (2022):11-17,
https://doi.org/10.2298/NTRP2201011L . .

TY  - JOUR
AU  - Spasojević, Milica
AU  - Plazinić, Milan
AU  - Luković, Milentije
AU  - Maričić, Aleksa
AU  - Spasojević, Miroslav
PY  - 2020
UR  - https://cherry.chem.bg.ac.rs/handle/123456789/4256
AB  - A nanostructured powder of the Ni86,0Fe9,8W1,3Cu2,9 alloy is deposited on a titanium cathode by electrodeposition from the citrate bath, at the current density of 400 mA cm−2. The powder particles are of a cauliflower and dendritic shape and composed of nanocrystals of the FCC phase of the solid solution of iron, tungsten and copper in nickel, captive in an amorphous matrix. The freshly deposited powder is thermally stable up to 160 °C. The annealing of the powder in the temperature range from 160 °C to 460 °C results in its structure relaxation. At temperatures higher than 460 °C, the amorphous phase in the powder is crystalizing and crystal grains of the FCC solid solution are growing. The structural changes caused by annealing, affect magnetic properties of the alloy. The cooled powders after the structure relaxation have higher magnetization, a lower loss of the active power and a lower coercive field. Crystallization of the amorphous phase and crystalline grain growth of the FCC phase causes a decrease in magnetization, an increase in the power loss and the power of coercive field.
PB  - Elsevier
T2  - Materials Chemistry and Physics
T1  - The effect of annealing and frequency of the external magnetic field on magnetic properties of nanostructured electrodeposit of the Ni86,0Fe9,8W1,3Cu2,9 alloy
VL  - 254
DO  - 10.1016/j.matchemphys.2020.123513
ER  - 

@article{
author = "Spasojević, Milica and Plazinić, Milan and Luković, Milentije and Maričić, Aleksa and Spasojević, Miroslav",
year = "2020",
abstract = "A nanostructured powder of the Ni86,0Fe9,8W1,3Cu2,9 alloy is deposited on a titanium cathode by electrodeposition from the citrate bath, at the current density of 400 mA cm−2. The powder particles are of a cauliflower and dendritic shape and composed of nanocrystals of the FCC phase of the solid solution of iron, tungsten and copper in nickel, captive in an amorphous matrix. The freshly deposited powder is thermally stable up to 160 °C. The annealing of the powder in the temperature range from 160 °C to 460 °C results in its structure relaxation. At temperatures higher than 460 °C, the amorphous phase in the powder is crystalizing and crystal grains of the FCC solid solution are growing. The structural changes caused by annealing, affect magnetic properties of the alloy. The cooled powders after the structure relaxation have higher magnetization, a lower loss of the active power and a lower coercive field. Crystallization of the amorphous phase and crystalline grain growth of the FCC phase causes a decrease in magnetization, an increase in the power loss and the power of coercive field.",
publisher = "Elsevier",
journal = "Materials Chemistry and Physics",
title = "The effect of annealing and frequency of the external magnetic field on magnetic properties of nanostructured electrodeposit of the Ni86,0Fe9,8W1,3Cu2,9 alloy",
volume = "254",
doi = "10.1016/j.matchemphys.2020.123513"
}

Spasojević, M., Plazinić, M., Luković, M., Maričić, A.,& Spasojević, M.. (2020). The effect of annealing and frequency of the external magnetic field on magnetic properties of nanostructured electrodeposit of the Ni86,0Fe9,8W1,3Cu2,9 alloy. in Materials Chemistry and Physics
Elsevier., 254.
https://doi.org/10.1016/j.matchemphys.2020.123513

Spasojević M, Plazinić M, Luković M, Maričić A, Spasojević M. The effect of annealing and frequency of the external magnetic field on magnetic properties of nanostructured electrodeposit of the Ni86,0Fe9,8W1,3Cu2,9 alloy. in Materials Chemistry and Physics. 2020;254.
doi:10.1016/j.matchemphys.2020.123513 .

Spasojević, Milica, Plazinić, Milan, Luković, Milentije, Maričić, Aleksa, Spasojević, Miroslav, "The effect of annealing and frequency of the external magnetic field on magnetic properties of nanostructured electrodeposit of the Ni86,0Fe9,8W1,3Cu2,9 alloy" in Materials Chemistry and Physics, 254 (2020),
https://doi.org/10.1016/j.matchemphys.2020.123513 . .