Investigation of structural and optical properties of zirconia dioxide nanoparticles by radiation and thermal methods

Imanova, Gunel; Agayev, T.N.; Jabarov, S. H.

doi:10.1142/s0217984921500500

Cited by 31 publications

(8 citation statements)

References 42 publications

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“…Originally silicon has been processed at T=473K, T=72 hours in the air environment, and after determination of the necessary weight is purified in special conditions and added to the ampoule (V=19 ml) which is thermally processed (T=773K). After heat treatment (T=673K) of silicon in an ampoule in vacuum conditions (P=10 -3 mm Hg) within 4 hours, it has been cooled, and the necessary amount of the double distilled water purified from air in special conditions [9] has been adsorbed on his surface. Then ampoules have been soldered and irradiated in special conditions (by continuous hashing of system by the vibrator with the purpose to achieve suspension of silicon particles in water) on a source 60 Co at the power of dose P=22 Rad/s.…”

Section: Experimental Partmentioning

confidence: 99%

Investigation on Process of the Water Radiolysis in the Nano Si+H2O System Under the Influence of Gamma – Quanta

Imanova¹

2022

Journal of Physical Chemistry and Functional Materials

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The radiation-chemical yield of the molecular hydrogen received under the influence of gamma quanta (60Co, P=22Rad/s, T=300K) to liquid water of constant volume (V=5 ml) in the process of a radiolysis of water at change of weight (m=0.01; 0.02; 0.06 and 0.12 g) and sizes of silicon particle (d=50 nanometers) is defined. It has been revealed that at increase in mass of the silicon added to water the radiation-chemical yield of the molecular hydrogen received in the process of a water radiolysis grows in direct ratio (m0.02 g) the stationary area is observed. In the Si+H2O system the maximum radiation-chemical yield of molecular hydrogen is equal to 10,9 molecules / 100eV at the sizes of silicon particle d=50 nanometer respectively. The mechanism explaining the received results is offered.

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Section: Experimental Partmentioning

confidence: 99%

Investigation on Process of the Water Radiolysis in the Nano Si+H2O System Under the Influence of Gamma – Quanta

Imanova¹

2022

Journal of Physical Chemistry and Functional Materials

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“…Therefore, these materials are widely used in all fields of science and technology. One of these applications is the method of obtaining molecular hydrogen from the conversion of water used for the transition from nuclear energy to hydrogen energy with the help of nanoscale catalysts [2][3][4][5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Generation During Thermal Processes of Water Decomposition on the Surface of Nano-ZrO2+3mol.%Y2O3

et al. 2023

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The study of physicochemical properties of nano-ZrO2+3mol.%Y2O3 was determined. The X-ray diffraction spectrum of the nano-ZrO2 and system nano-ZrO2+3 mol.%Y2O3 compound was drawn by the Ritveld method and the crystal structure was determined at different temperatures (T = 373, 473, 573, 673 K) and under normal conditions. The energy of the arrangement of H2 as a result of the decay of H2O, on the surface of nano-ZrO2+3mol.%Y2O3 was considered. Impacts of adsorption and desorption preparation of ZrO2+3mol.%Y2O3 nanoparticles were considered at diverse (T = 373, 473, 573, 673 K) temperatures. The thought of H2 in warm forms at nano-ZrO2+3mol.%Y2O3 framework expanded. This tells about hydrogen era by water part in close future. Nano-ZrO2 and system nano-ZrO2+3mol.%Y2O3 with the temperature range of T = 373, 473, 573, 673 K have been studied by SEM analysis. These results are promising of hydrogen generation by water splitting in near future. HIGHLIGHTS First innovative research article in this area Importance of the thermal in water splitting for hydrogen generation Design and optimization of water splitting for hydrogen generation Future of hydrogen generation at a large scale economically GRAPHICAL ABSTRACT

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“…Nano-ZrO2 has good thermal insulation and dielectric properties over a wide temperature range, which allows it to be considered as a promising material in the field of microelectronics and the use of construction materials [9][10][11][12][13][14]. Nanostructure materials possess developed surfaces and increased defects on the boundary of particles, which are of remarkable significance in radiation-heterogeneous processes with their participation, and during the progression of highly sensitive detectors of ionizing radiation [15][16][17][18]. Heating devices operate at fairly high temperatures, using nanoparticle ZrO2 to ensure their high quality.…”

Section: Introductionmentioning

confidence: 99%

Molecular hydrogen production by radiolysis of water on the surface of nano-ZrO2 under the influence of gamma rays

Imanova

2022

Synth. Sinter.

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In this research, the radiation-heterogeneous processes of water decomposition on the surface of zirconium dioxide nanoparticles (n-ZrO2) were studied. The kinetics of buildup of molecular hydrogen during the radiolytic processes of water decomposition was also examined. The production of H2 and H2O2 through water radiolysis was investigated to develop a computational model and disclose the kinetic behavior of water radiolysis. The enthalpy of ZrO2 nanoparticles was studied at the temperature range T=1200-2900 K, in which ZrO2 nanoparticles has a two-phase transition. Some of the electrons were transported to the surface of the nanoparticles during the physical and physicochemical stages of the process and emitted into the water. At the same time, the migration of energy carriers in radioactively active oxide compounds changed at different intervals depending on the composition, structural stability, and electro-physical properties of the oxides.

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Investigation of structural and optical properties of zirconia dioxide nanoparticles by radiation and thermal methods

Cited by 31 publications

References 42 publications

Investigation on Process of the Water Radiolysis in the Nano Si+H2O System Under the Influence of Gamma – Quanta

Investigation on Process of the Water Radiolysis in the Nano Si+H2O System Under the Influence of Gamma – Quanta

Hydrogen Generation During Thermal Processes of Water Decomposition on the Surface of Nano-ZrO2+3mol.%Y2O3

Molecular hydrogen production by radiolysis of water on the surface of nano-ZrO2 under the influence of gamma rays

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