TY  - JOUR
AU  - Spasojević, M.
AU  - Ribić-Zelenović, Lenka
AU  - Maricić, A.
AU  - Spasojević, Pavle
PY  - 2014
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2846
AB  - A dark gray nanostructured coating of an alloy composed of 87.3 wt.% Ni, 11.3 wt.% Fe and 1.4 wt.% W (Ni87.3Fe11.3W1.4) was electrodeposited from an ammonia citrate bath on a titanium cathode at a current density of 500 mA cm(-2). A cathodic polarization curve was recorded and dependence of the current efficiency of alloy deposition on current density was determined. Partial polarization curves for alloy deposition and hydrogen evolution were also measured. Alloy deposition at current densities of up to 300 mA cm(-2) is an activation-controlled process which turns into a diffusion-controlled process at higher current densities. At potentials more positive than -960 mV, hydrogen is evolved from NH4+ and (HCit)(3-) ions (where (HCit)(3-) denotes triply deprotonated citric acid, C6H5O73-). At potentials more negative than -960 mV, hydrogen evolution from water is the dominating reaction. SEM images show that the surface of the deposit obtained at 500 mA cm(-2) has a globular structure containing a large number of craters, mostly located between the globules. XRD analysis revealed that the alloy contains an amorphous matrix with embedded nanocrystals of the FCC-structured solid solution of Fe and Win Ni with a mean particle size of 8.8 nm. The deposit has a high internal microstrain value and a high density of chaotically distributed dislocations. Heating and milling the alloy cause structural changes involving changes in the magnetic properties of the alloy. Structural relaxation takes place in the temperature interval of 80 degrees C to 420 degrees C. In this temperature range, magnetization of both as-deposited and milled alloy samples increases with increasing temperature, reaching maximum at a certain temperature, but decreases thereafter with further heating. During structural relaxation, short-term structural arrangement facilitates the expansion and orientation of magnetic domains, leading to increased magnetization of the alloy. The abrupt decline in magnetization at higher temperatures is the result of a heatinduced change in magnetic domain orientation. Annealing the alloy at temperatures above 420 degrees C causes amorphous phase crystallization and growth of crystal grains of the FCC-structured solid solution of Fe and W in Ni, as well as a simultaneous decrease in internal microstrain and mean density of chaotically distributed dislocations. The same structural changes, somewhat lower in intensity, are also caused by alloy milling. The new state of the microstructure achieved through annealing and milling is best illustrated by the mean crystal size. The increase in mean crystal size results in a shift of the Curie temperature towards lower temperatures, whereas magnetization increases at first, reaching maximum at a certain mean crystal size, but decreases, thereafter, with a further increase in mean crystal size.
PB  - Elsevier, Amsterdam
T2  - Powder Technology
T1  - Structure and magnetic properties of electrodeposited Ni87.3Fe11.3W1.4 alloy
EP  - 447
SP  - 439
VL  - 254
DO  - 10.1016/j.powtec.2014.01.017
ER  - 

@article{
author = "Spasojević, M. and Ribić-Zelenović, Lenka and Maricić, A. and Spasojević, Pavle",
year = "2014",
abstract = "A dark gray nanostructured coating of an alloy composed of 87.3 wt.% Ni, 11.3 wt.% Fe and 1.4 wt.% W (Ni87.3Fe11.3W1.4) was electrodeposited from an ammonia citrate bath on a titanium cathode at a current density of 500 mA cm(-2). A cathodic polarization curve was recorded and dependence of the current efficiency of alloy deposition on current density was determined. Partial polarization curves for alloy deposition and hydrogen evolution were also measured. Alloy deposition at current densities of up to 300 mA cm(-2) is an activation-controlled process which turns into a diffusion-controlled process at higher current densities. At potentials more positive than -960 mV, hydrogen is evolved from NH4+ and (HCit)(3-) ions (where (HCit)(3-) denotes triply deprotonated citric acid, C6H5O73-). At potentials more negative than -960 mV, hydrogen evolution from water is the dominating reaction. SEM images show that the surface of the deposit obtained at 500 mA cm(-2) has a globular structure containing a large number of craters, mostly located between the globules. XRD analysis revealed that the alloy contains an amorphous matrix with embedded nanocrystals of the FCC-structured solid solution of Fe and Win Ni with a mean particle size of 8.8 nm. The deposit has a high internal microstrain value and a high density of chaotically distributed dislocations. Heating and milling the alloy cause structural changes involving changes in the magnetic properties of the alloy. Structural relaxation takes place in the temperature interval of 80 degrees C to 420 degrees C. In this temperature range, magnetization of both as-deposited and milled alloy samples increases with increasing temperature, reaching maximum at a certain temperature, but decreases thereafter with further heating. During structural relaxation, short-term structural arrangement facilitates the expansion and orientation of magnetic domains, leading to increased magnetization of the alloy. The abrupt decline in magnetization at higher temperatures is the result of a heatinduced change in magnetic domain orientation. Annealing the alloy at temperatures above 420 degrees C causes amorphous phase crystallization and growth of crystal grains of the FCC-structured solid solution of Fe and W in Ni, as well as a simultaneous decrease in internal microstrain and mean density of chaotically distributed dislocations. The same structural changes, somewhat lower in intensity, are also caused by alloy milling. The new state of the microstructure achieved through annealing and milling is best illustrated by the mean crystal size. The increase in mean crystal size results in a shift of the Curie temperature towards lower temperatures, whereas magnetization increases at first, reaching maximum at a certain mean crystal size, but decreases, thereafter, with a further increase in mean crystal size.",
publisher = "Elsevier, Amsterdam",
journal = "Powder Technology",
title = "Structure and magnetic properties of electrodeposited Ni87.3Fe11.3W1.4 alloy",
pages = "447-439",
volume = "254",
doi = "10.1016/j.powtec.2014.01.017"
}

Spasojević, M., Ribić-Zelenović, L., Maricić, A.,& Spasojević, P.. (2014). Structure and magnetic properties of electrodeposited Ni87.3Fe11.3W1.4 alloy. in Powder Technology
Elsevier, Amsterdam., 254, 439-447.
https://doi.org/10.1016/j.powtec.2014.01.017

Spasojević M, Ribić-Zelenović L, Maricić A, Spasojević P. Structure and magnetic properties of electrodeposited Ni87.3Fe11.3W1.4 alloy. in Powder Technology. 2014;254:439-447.
doi:10.1016/j.powtec.2014.01.017 .

Spasojević, M., Ribić-Zelenović, Lenka, Maricić, A., Spasojević, Pavle, "Structure and magnetic properties of electrodeposited Ni87.3Fe11.3W1.4 alloy" in Powder Technology, 254 (2014):439-447,
https://doi.org/10.1016/j.powtec.2014.01.017 . .

TY  - JOUR
AU  - Spasojević, M.
AU  - Cirović, N.
AU  - Ribić-Zelenović, Lenka
AU  - Spasojević, Pavle
AU  - Maricić, A.
PY  - 2014
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2666
AB  - Nanostructured nickel-iron-tungsten alloy coatings were electrodeposited from an ammonia citrate bath on steel and copper substrates at current densities in the range of 50 to 300 mA cm(-2). The contents of iron and tungsten in the alloy increase and that of nickel decreases with increasing deposition current density. At current densities below 100 mA cm(-2), smooth shiny coatings with no cracks and craters are deposited. Higher current densities result in matte coatings developing cracks and craters. XRD analysis showed that the coatings contain nanocrystals of FCC structured solid solution of iron and tungsten in nickel embedded in an amorphous matrix. Increasing deposition current density leads to an increase in the amorphous phase content and a decrease in both the content and mean crystallite size of the FCC phase. The coatings with an increased amorphous phase content and a decreased mean FCC crystallite size exhibit lower magnetization and reduced hardness. During annealing at temperatures up to 400 degrees C, the alloy undergoes structural relaxation along with short-range structural arrangement, resulting in increased magnetization and hardness. At temperatures above 500 degrees C, annealing leads to amorphous phase crystallization and crystal grain growth in the FCC solid solution, thus leading to reduction in both magnetization and hardness.
PB  - Electrochemical Soc Inc, Pennington
T2  - Journal of the Electrochemical Society
T1  - Effect of Deposition Current Density and Annealing Temperature on the Microstructure, Hardness and Magnetic Properties of Nanostructured Nickel-Iron-Tungsten Alloys
EP  - D469
IS  - 10
SP  - D463
VL  - 161
DO  - 10.1149/2.0041410jes
ER  - 

@article{
author = "Spasojević, M. and Cirović, N. and Ribić-Zelenović, Lenka and Spasojević, Pavle and Maricić, A.",
year = "2014",
abstract = "Nanostructured nickel-iron-tungsten alloy coatings were electrodeposited from an ammonia citrate bath on steel and copper substrates at current densities in the range of 50 to 300 mA cm(-2). The contents of iron and tungsten in the alloy increase and that of nickel decreases with increasing deposition current density. At current densities below 100 mA cm(-2), smooth shiny coatings with no cracks and craters are deposited. Higher current densities result in matte coatings developing cracks and craters. XRD analysis showed that the coatings contain nanocrystals of FCC structured solid solution of iron and tungsten in nickel embedded in an amorphous matrix. Increasing deposition current density leads to an increase in the amorphous phase content and a decrease in both the content and mean crystallite size of the FCC phase. The coatings with an increased amorphous phase content and a decreased mean FCC crystallite size exhibit lower magnetization and reduced hardness. During annealing at temperatures up to 400 degrees C, the alloy undergoes structural relaxation along with short-range structural arrangement, resulting in increased magnetization and hardness. At temperatures above 500 degrees C, annealing leads to amorphous phase crystallization and crystal grain growth in the FCC solid solution, thus leading to reduction in both magnetization and hardness.",
publisher = "Electrochemical Soc Inc, Pennington",
journal = "Journal of the Electrochemical Society",
title = "Effect of Deposition Current Density and Annealing Temperature on the Microstructure, Hardness and Magnetic Properties of Nanostructured Nickel-Iron-Tungsten Alloys",
pages = "D469-D463",
number = "10",
volume = "161",
doi = "10.1149/2.0041410jes"
}

Spasojević, M., Cirović, N., Ribić-Zelenović, L., Spasojević, P.,& Maricić, A.. (2014). Effect of Deposition Current Density and Annealing Temperature on the Microstructure, Hardness and Magnetic Properties of Nanostructured Nickel-Iron-Tungsten Alloys. in Journal of the Electrochemical Society
Electrochemical Soc Inc, Pennington., 161(10), D463-D469.
https://doi.org/10.1149/2.0041410jes

Spasojević M, Cirović N, Ribić-Zelenović L, Spasojević P, Maricić A. Effect of Deposition Current Density and Annealing Temperature on the Microstructure, Hardness and Magnetic Properties of Nanostructured Nickel-Iron-Tungsten Alloys. in Journal of the Electrochemical Society. 2014;161(10):D463-D469.
doi:10.1149/2.0041410jes .

Spasojević, M., Cirović, N., Ribić-Zelenović, Lenka, Spasojević, Pavle, Maricić, A., "Effect of Deposition Current Density and Annealing Temperature on the Microstructure, Hardness and Magnetic Properties of Nanostructured Nickel-Iron-Tungsten Alloys" in Journal of the Electrochemical Society, 161, no. 10 (2014):D463-D469,
https://doi.org/10.1149/2.0041410jes . .

TY  - JOUR
AU  - Pesić, O.
AU  - Spasojević, M.
AU  - Jordović, Branka
AU  - Spasojević, Pavle
AU  - Maricić, A.
PY  - 2014
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2684
AB  - Nanostructured nickel-cobalt-molybdenum alloy powders were electrodeposited from an ammonium sulfate bath. The powders mostly consist of an amorphous phase and a very small amount of nanocrystals with an mean size of less than 3 nm. An increase in deposition current density increases the amorphous phase percentage, the density of chaotically distributed dislocations and internal microstrains in the powders, while decreasing the mean nanocrystal size. The temperature range over which the structural relaxation of the powders deposited at higher current densities occurs is shifted towards lower temperatures. A change in relative magnetic permeability during structural relaxation is higher in powders deposited at higher current densities. Powder crystallization takes place at temperatures above 700 degrees C. The formation of the stable crystal structure causes a decrease in relative magnetic permeability.
PB  - Međunarodni Institut za nauku o sinterovanju, Beograd
T2  - Science of Sintering
T1  - Effect of Electrodeposition Current Density on the Microstructure and Magnetic Properties of Nickel-cobalt-molybdenum Alloy Powders
EP  - 127
IS  - 1
SP  - 117
VL  - 46
DO  - 10.2298/SOS1401117P
ER  - 

@article{
author = "Pesić, O. and Spasojević, M. and Jordović, Branka and Spasojević, Pavle and Maricić, A.",
year = "2014",
abstract = "Nanostructured nickel-cobalt-molybdenum alloy powders were electrodeposited from an ammonium sulfate bath. The powders mostly consist of an amorphous phase and a very small amount of nanocrystals with an mean size of less than 3 nm. An increase in deposition current density increases the amorphous phase percentage, the density of chaotically distributed dislocations and internal microstrains in the powders, while decreasing the mean nanocrystal size. The temperature range over which the structural relaxation of the powders deposited at higher current densities occurs is shifted towards lower temperatures. A change in relative magnetic permeability during structural relaxation is higher in powders deposited at higher current densities. Powder crystallization takes place at temperatures above 700 degrees C. The formation of the stable crystal structure causes a decrease in relative magnetic permeability.",
publisher = "Međunarodni Institut za nauku o sinterovanju, Beograd",
journal = "Science of Sintering",
title = "Effect of Electrodeposition Current Density on the Microstructure and Magnetic Properties of Nickel-cobalt-molybdenum Alloy Powders",
pages = "127-117",
number = "1",
volume = "46",
doi = "10.2298/SOS1401117P"
}

Pesić, O., Spasojević, M., Jordović, B., Spasojević, P.,& Maricić, A.. (2014). Effect of Electrodeposition Current Density on the Microstructure and Magnetic Properties of Nickel-cobalt-molybdenum Alloy Powders. in Science of Sintering
Međunarodni Institut za nauku o sinterovanju, Beograd., 46(1), 117-127.
https://doi.org/10.2298/SOS1401117P

Pesić O, Spasojević M, Jordović B, Spasojević P, Maricić A. Effect of Electrodeposition Current Density on the Microstructure and Magnetic Properties of Nickel-cobalt-molybdenum Alloy Powders. in Science of Sintering. 2014;46(1):117-127.
doi:10.2298/SOS1401117P .

Pesić, O., Spasojević, M., Jordović, Branka, Spasojević, Pavle, Maricić, A., "Effect of Electrodeposition Current Density on the Microstructure and Magnetic Properties of Nickel-cobalt-molybdenum Alloy Powders" in Science of Sintering, 46, no. 1 (2014):117-127,
https://doi.org/10.2298/SOS1401117P . .

TY  - JOUR
AU  - Spasojević, M.
AU  - Maricić, A.
AU  - Ribić-Zelenović, Lenka
AU  - Krstajić, Nedeljko V.
AU  - Spasojević, Pavle
PY  - 2013
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2522
AB  - Ni79.1Co18.6Cu2.3 powder was obtained by electrochemical deposition from an ammonium sulfate bath. The structure and surface morphology of the powder were detected by X-ray diffraction (XRD) and scanning electron microscopy (SEM), respectively. The electrochemically obtained Ni79.1Co18.6Cu2.3 alloy contained an amorphous phase and nanocrystals with an average size of 6.8 nm of FCC phase of the solid solution of cobalt and copper in nickel. Nanocrystals were characterized by a high average microstrain value and high minimum density of chaotically distributed dislocations. X-ray analysis also showed that powder hydrogenation at an elevated temperature of up to 200 degrees C did not change unit cell parameters and mean crystallite size value. SEM images show the formation of two shapes of powder particles: large cauliflower-like particles and small dendritic ones. Powder pressing at 10 MPa and at 25 degrees C gave samples that were analyzed for hydrogen absorption/desorption within the temperature range of 160-200 degrees C. Changes in electrical resistivity during absorption/desorption were monitored. The reciprocal value of resistivity (electrical conductivity) was found to increase linearly with increasing amount of absorbed hydrogen. The experimental results were used to propose an absorption/desorption mechanism. The adsorbed hydrogen molecule dissociates on alloy surface, forming adsorbed atoms. Adatoms penetrate and diffuse into the bulk of the alloy, simultaneously donating their electrons to the conduction band of the alloy. The increase in the concentration of free electrons induces a decrease in electrical resistivity. The overall absorption rate during initial absorption is determined by the dissociation of adsorbed hydrogen molecules. At a later stage, the diffusion of H+ ions into the alloy bulk was found to be the rate determining step. The rate of the desorption reaction during the initial stage is governed by the recombination of adsorbed hydrogen atoms. Over time, H+ diffusion becomes the slowest step in the mechanism, hence determining the desorption rate.
PB  - Elsevier Science Sa, Lausanne
T2  - Journal of Alloys and Compounds
T1  - The kinetics of hydrogen absorption/desorption within nanostructured composite Ni79.1Co18.6Cu2.3 alloy using resistometry
EP  - 666
SP  - 660
VL  - 551
DO  - 10.1016/j.jallcom.2012.10.187
ER  - 

@article{
author = "Spasojević, M. and Maricić, A. and Ribić-Zelenović, Lenka and Krstajić, Nedeljko V. and Spasojević, Pavle",
year = "2013",
abstract = "Ni79.1Co18.6Cu2.3 powder was obtained by electrochemical deposition from an ammonium sulfate bath. The structure and surface morphology of the powder were detected by X-ray diffraction (XRD) and scanning electron microscopy (SEM), respectively. The electrochemically obtained Ni79.1Co18.6Cu2.3 alloy contained an amorphous phase and nanocrystals with an average size of 6.8 nm of FCC phase of the solid solution of cobalt and copper in nickel. Nanocrystals were characterized by a high average microstrain value and high minimum density of chaotically distributed dislocations. X-ray analysis also showed that powder hydrogenation at an elevated temperature of up to 200 degrees C did not change unit cell parameters and mean crystallite size value. SEM images show the formation of two shapes of powder particles: large cauliflower-like particles and small dendritic ones. Powder pressing at 10 MPa and at 25 degrees C gave samples that were analyzed for hydrogen absorption/desorption within the temperature range of 160-200 degrees C. Changes in electrical resistivity during absorption/desorption were monitored. The reciprocal value of resistivity (electrical conductivity) was found to increase linearly with increasing amount of absorbed hydrogen. The experimental results were used to propose an absorption/desorption mechanism. The adsorbed hydrogen molecule dissociates on alloy surface, forming adsorbed atoms. Adatoms penetrate and diffuse into the bulk of the alloy, simultaneously donating their electrons to the conduction band of the alloy. The increase in the concentration of free electrons induces a decrease in electrical resistivity. The overall absorption rate during initial absorption is determined by the dissociation of adsorbed hydrogen molecules. At a later stage, the diffusion of H+ ions into the alloy bulk was found to be the rate determining step. The rate of the desorption reaction during the initial stage is governed by the recombination of adsorbed hydrogen atoms. Over time, H+ diffusion becomes the slowest step in the mechanism, hence determining the desorption rate.",
publisher = "Elsevier Science Sa, Lausanne",
journal = "Journal of Alloys and Compounds",
title = "The kinetics of hydrogen absorption/desorption within nanostructured composite Ni79.1Co18.6Cu2.3 alloy using resistometry",
pages = "666-660",
volume = "551",
doi = "10.1016/j.jallcom.2012.10.187"
}

Spasojević, M., Maricić, A., Ribić-Zelenović, L., Krstajić, N. V.,& Spasojević, P.. (2013). The kinetics of hydrogen absorption/desorption within nanostructured composite Ni79.1Co18.6Cu2.3 alloy using resistometry. in Journal of Alloys and Compounds
Elsevier Science Sa, Lausanne., 551, 660-666.
https://doi.org/10.1016/j.jallcom.2012.10.187

Spasojević M, Maricić A, Ribić-Zelenović L, Krstajić NV, Spasojević P. The kinetics of hydrogen absorption/desorption within nanostructured composite Ni79.1Co18.6Cu2.3 alloy using resistometry. in Journal of Alloys and Compounds. 2013;551:660-666.
doi:10.1016/j.jallcom.2012.10.187 .

Spasojević, M., Maricić, A., Ribić-Zelenović, Lenka, Krstajić, Nedeljko V., Spasojević, Pavle, "The kinetics of hydrogen absorption/desorption within nanostructured composite Ni79.1Co18.6Cu2.3 alloy using resistometry" in Journal of Alloys and Compounds, 551 (2013):660-666,
https://doi.org/10.1016/j.jallcom.2012.10.187 . .