TY  - JOUR
AU  - Stojanović, Nemanja
AU  - Kalezić-Glisović, Aleksandra
AU  - Janićijević, Aco
AU  - Maricić, Aleksa
PY  - 2020
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4362
AB  - Multiferroic systems are attractive to the researches worldwide due to diversity of existing applications, as well as possible novel ones. In order to contribute to understanding of the processes that take place within the structure of such a system, we subjected it to mechanochemical activation and thermal treatment. Powdery mixtures of iron and barium titanate in a mass ratio of 30% Fe and 70% BaTiO3 were activated in a planetary ball mill for time duration of 30 to 300 min and subsequently sintered at 1200 degrees C in the atmosphere of air. During the activation the system undergoes structural phase transitions, whereby the content of iron and its oxides changes. The highest Fe content was observed in the sample activated for 270 min, with local maxima in crystallite size and microstrain values and a minimum in dislocation density. The complex dielectric permittivity changes in the applied radio frequency field, rangingfrom 176.9 pF/m in thesample activated for 90 min to 918.1 pF/m in the sample activated for 180 min. As the frequency of the field increases, an exponential decrease in the magnetic with a simultaneous increase in the electrical energy losses is noticeable. The system exhibits ferromagnetic resonance, whereby longer activation in the mill shifts the resonant frequency to higher values. Negative electrical resistance was observed in all analyzed samples. The activation time changes both the demagnetization temperature and the Curie temperature of the samples undergoing heating and cooling cycles in the external permanent magnetic field. Curie temperature is the highest in the sample activated for 240 min. Thermal treatment increases the initial magnetization of all samples, with the most pronounced increase of similar to 95% in the sample activated for 300 min.
PB  - Međunarodni Institut za nauku o sinterovanju, Beograd
T2  - Science of Sintering
T1  - Evolution of Structural and Functional Properties of the Fe/BaTiO3 System Guided by Mechanochemical and Thermal Treatment
EP  - 176
IS  - 2
SP  - 163
VL  - 52
DO  - 10.2298/SOS2002163S
ER  - 

@article{
author = "Stojanović, Nemanja and Kalezić-Glisović, Aleksandra and Janićijević, Aco and Maricić, Aleksa",
year = "2020",
abstract = "Multiferroic systems are attractive to the researches worldwide due to diversity of existing applications, as well as possible novel ones. In order to contribute to understanding of the processes that take place within the structure of such a system, we subjected it to mechanochemical activation and thermal treatment. Powdery mixtures of iron and barium titanate in a mass ratio of 30% Fe and 70% BaTiO3 were activated in a planetary ball mill for time duration of 30 to 300 min and subsequently sintered at 1200 degrees C in the atmosphere of air. During the activation the system undergoes structural phase transitions, whereby the content of iron and its oxides changes. The highest Fe content was observed in the sample activated for 270 min, with local maxima in crystallite size and microstrain values and a minimum in dislocation density. The complex dielectric permittivity changes in the applied radio frequency field, rangingfrom 176.9 pF/m in thesample activated for 90 min to 918.1 pF/m in the sample activated for 180 min. As the frequency of the field increases, an exponential decrease in the magnetic with a simultaneous increase in the electrical energy losses is noticeable. The system exhibits ferromagnetic resonance, whereby longer activation in the mill shifts the resonant frequency to higher values. Negative electrical resistance was observed in all analyzed samples. The activation time changes both the demagnetization temperature and the Curie temperature of the samples undergoing heating and cooling cycles in the external permanent magnetic field. Curie temperature is the highest in the sample activated for 240 min. Thermal treatment increases the initial magnetization of all samples, with the most pronounced increase of similar to 95% in the sample activated for 300 min.",
publisher = "Međunarodni Institut za nauku o sinterovanju, Beograd",
journal = "Science of Sintering",
title = "Evolution of Structural and Functional Properties of the Fe/BaTiO3 System Guided by Mechanochemical and Thermal Treatment",
pages = "176-163",
number = "2",
volume = "52",
doi = "10.2298/SOS2002163S"
}

Stojanović, N., Kalezić-Glisović, A., Janićijević, A.,& Maricić, A.. (2020). Evolution of Structural and Functional Properties of the Fe/BaTiO3 System Guided by Mechanochemical and Thermal Treatment. in Science of Sintering
Međunarodni Institut za nauku o sinterovanju, Beograd., 52(2), 163-176.
https://doi.org/10.2298/SOS2002163S

Stojanović N, Kalezić-Glisović A, Janićijević A, Maricić A. Evolution of Structural and Functional Properties of the Fe/BaTiO3 System Guided by Mechanochemical and Thermal Treatment. in Science of Sintering. 2020;52(2):163-176.
doi:10.2298/SOS2002163S .

Stojanović, Nemanja, Kalezić-Glisović, Aleksandra, Janićijević, Aco, Maricić, Aleksa, "Evolution of Structural and Functional Properties of the Fe/BaTiO3 System Guided by Mechanochemical and Thermal Treatment" in Science of Sintering, 52, no. 2 (2020):163-176,
https://doi.org/10.2298/SOS2002163S . .

TY  - JOUR
AU  - Ćirović, Nataša
AU  - Spasojević, Pavle
AU  - Ribić-Zelenović, Lenka
AU  - Masković, Pavle
AU  - Maricić, Aleksa
AU  - Spasojević, Miroslav
PY  - 2016
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/3282
AB  - Nanostructured nickel-iron-tungsten alloys were produced by electrodeposition from an ammoniacal citrate bath. The tungsten content of the alloy ranged from 0.8 wt.% to 11 wt.%, and the crystal grain size of the FCC phase of the solid solution of iron and tungsten in nickel was between 14 nm and 3.3 nm. The amorphous phase content of the alloy increases with decreasing crystal grain size. As the amorphous phase content increases, the magnetization, electrical conductivity and hardness of the alloy decrease. Annealing the alloy to crystallization temperature results in structural relaxation during which the alloy undergoes short-range ordering in conjunction with decreases in the density of chaotically distributed dislocations and internal microstrain level, which increases the exchange integral value, the electronic density of states at the Fermi level, the mean free path of electrons, the ordering and the mean size of cluster in the sliding plane and results in more uniform orientation of dipole moments of certain nanoparticles. These changes: a) increase the mobility of magnetic domain walls, facilitate the orientation of domains in the external magnetic field and cause an increase in magnetization; b) cause a decrease in electrical resistance, and c) impede the sliding of grain boundaries and increase the hardness of the alloy. Annealing the alloys at temperatures above 400 degrees C results in amorphous phase crystallization and larger crystal grains of the FCC phase, along with a decrease in the density of chaotically distributed dislocations and a decrease in internal microstrain level. The formation of larger crystal grains reduces the hardness of the alloy, decreases its specific electrical resistance and impedes both the orientation of certain magnetic domains and the shift of walls of already oriented domains, thus inducing a decrease in magnetization. The heat released during the milling of Ni87.3Fe11.3W1.4 alloy with FCC-phase crystal grains 8.8 nm in average size causes amorphous phase crystallization, FCC crystal grain growth and an increase in magnetization. Alloys with relatively high tungsten content (11 wt. %) have an inhomogeneous composition, a high proportion of the amorphous phase and FCC crystal grains with an average size of 3.3 nm. This microstructure results in magnetic domains that have different and relatively low thermal stabilities and relatively low degrees of magnetization.
PB  - Međunarodni Institut za nauku o sinterovanju, Beograd
T2  - Science of Sintering
T1  - Synthesis, Structure and Properties of Nickel-Iron-Tungsten Alloy Electrodeposits PART II: Effect of Microstructure on Hardness, Electrical and Magnetic Properties
EP  - 16
IS  - 1
SP  - 1
VL  - 48
DO  - 10.2298/SOS1601001C
ER  - 

@article{
author = "Ćirović, Nataša and Spasojević, Pavle and Ribić-Zelenović, Lenka and Masković, Pavle and Maricić, Aleksa and Spasojević, Miroslav",
year = "2016",
abstract = "Nanostructured nickel-iron-tungsten alloys were produced by electrodeposition from an ammoniacal citrate bath. The tungsten content of the alloy ranged from 0.8 wt.% to 11 wt.%, and the crystal grain size of the FCC phase of the solid solution of iron and tungsten in nickel was between 14 nm and 3.3 nm. The amorphous phase content of the alloy increases with decreasing crystal grain size. As the amorphous phase content increases, the magnetization, electrical conductivity and hardness of the alloy decrease. Annealing the alloy to crystallization temperature results in structural relaxation during which the alloy undergoes short-range ordering in conjunction with decreases in the density of chaotically distributed dislocations and internal microstrain level, which increases the exchange integral value, the electronic density of states at the Fermi level, the mean free path of electrons, the ordering and the mean size of cluster in the sliding plane and results in more uniform orientation of dipole moments of certain nanoparticles. These changes: a) increase the mobility of magnetic domain walls, facilitate the orientation of domains in the external magnetic field and cause an increase in magnetization; b) cause a decrease in electrical resistance, and c) impede the sliding of grain boundaries and increase the hardness of the alloy. Annealing the alloys at temperatures above 400 degrees C results in amorphous phase crystallization and larger crystal grains of the FCC phase, along with a decrease in the density of chaotically distributed dislocations and a decrease in internal microstrain level. The formation of larger crystal grains reduces the hardness of the alloy, decreases its specific electrical resistance and impedes both the orientation of certain magnetic domains and the shift of walls of already oriented domains, thus inducing a decrease in magnetization. The heat released during the milling of Ni87.3Fe11.3W1.4 alloy with FCC-phase crystal grains 8.8 nm in average size causes amorphous phase crystallization, FCC crystal grain growth and an increase in magnetization. Alloys with relatively high tungsten content (11 wt. %) have an inhomogeneous composition, a high proportion of the amorphous phase and FCC crystal grains with an average size of 3.3 nm. This microstructure results in magnetic domains that have different and relatively low thermal stabilities and relatively low degrees of magnetization.",
publisher = "Međunarodni Institut za nauku o sinterovanju, Beograd",
journal = "Science of Sintering",
title = "Synthesis, Structure and Properties of Nickel-Iron-Tungsten Alloy Electrodeposits PART II: Effect of Microstructure on Hardness, Electrical and Magnetic Properties",
pages = "16-1",
number = "1",
volume = "48",
doi = "10.2298/SOS1601001C"
}

Ćirović, N., Spasojević, P., Ribić-Zelenović, L., Masković, P., Maricić, A.,& Spasojević, M.. (2016). Synthesis, Structure and Properties of Nickel-Iron-Tungsten Alloy Electrodeposits PART II: Effect of Microstructure on Hardness, Electrical and Magnetic Properties. in Science of Sintering
Međunarodni Institut za nauku o sinterovanju, Beograd., 48(1), 1-16.
https://doi.org/10.2298/SOS1601001C

Ćirović N, Spasojević P, Ribić-Zelenović L, Masković P, Maricić A, Spasojević M. Synthesis, Structure and Properties of Nickel-Iron-Tungsten Alloy Electrodeposits PART II: Effect of Microstructure on Hardness, Electrical and Magnetic Properties. in Science of Sintering. 2016;48(1):1-16.
doi:10.2298/SOS1601001C .

Ćirović, Nataša, Spasojević, Pavle, Ribić-Zelenović, Lenka, Masković, Pavle, Maricić, Aleksa, Spasojević, Miroslav, "Synthesis, Structure and Properties of Nickel-Iron-Tungsten Alloy Electrodeposits PART II: Effect of Microstructure on Hardness, Electrical and Magnetic Properties" in Science of Sintering, 48, no. 1 (2016):1-16,
https://doi.org/10.2298/SOS1601001C . .