The study of processes affecting the radiation resistance of TiO2 powders after heating and modification with SiO2 nanoparticles

M. M. Mikhailov, S. A. Yuryev, G. E. Remnev, R. V. Sazonov, V. A. Vlasov, G. E. Kholodnaya

Research output: Contribution to journalArticle

5 Citations (Scopus)

Abstract

We have investigated the processes occurring within titanium dioxide powders heated and modified by silicon dioxide nanoparticles at 150, 400, and 800 °C. It has been figured out that the mentioned modification stipulates the increase in the powders’ radiation resistance. While investigating, we employed methods of the near-/mid-infrared regions spectrophotometry, derivatography, and mass spectrometry. The research results show that the increase in the radiation resistance at the heating is stipulated by a number of factors, namely (1) the desorption of the physically/chemically bound gases, (2) upfilling of the released bonds with the oxygen molecules, and (3) the improvement of titanium dioxide stoichiometry on the surface. The after-modification radiation resistance increases excessively (as opposed to the heating) due to the fact that the electron–hole pairs relaxate on the nanoparticles, which precipitate onto the surface of titanium dioxide powder.

Original languageEnglish
Pages (from-to)1-10
Number of pages10
JournalJournal of Thermal Analysis and Calorimetry
Volume130
Issue number2
DOIs
Publication statusAccepted/In press - 26 Apr 2017

Fingerprint

radiation tolerance
titanium oxides
Powders
Nanoparticles
Radiation
Heating
nanoparticles
heating
Spectrophotometry
spectrophotometry
Stoichiometry
Silicon Dioxide
spectroscopy
Mass spectrometry
Precipitates
stoichiometry
precipitates
Desorption
mass spectroscopy
Gases

Keywords

  • Electron irradiation
  • Heating
  • Modification
  • Silicon dioxide
  • Titanium dioxide

ASJC Scopus subject areas

  • Condensed Matter Physics
  • Physical and Theoretical Chemistry

Cite this

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title = "The study of processes affecting the radiation resistance of TiO2 powders after heating and modification with SiO2 nanoparticles",
abstract = "We have investigated the processes occurring within titanium dioxide powders heated and modified by silicon dioxide nanoparticles at 150, 400, and 800 °C. It has been figured out that the mentioned modification stipulates the increase in the powders’ radiation resistance. While investigating, we employed methods of the near-/mid-infrared regions spectrophotometry, derivatography, and mass spectrometry. The research results show that the increase in the radiation resistance at the heating is stipulated by a number of factors, namely (1) the desorption of the physically/chemically bound gases, (2) upfilling of the released bonds with the oxygen molecules, and (3) the improvement of titanium dioxide stoichiometry on the surface. The after-modification radiation resistance increases excessively (as opposed to the heating) due to the fact that the electron–hole pairs relaxate on the nanoparticles, which precipitate onto the surface of titanium dioxide powder.",
keywords = "Electron irradiation, Heating, Modification, Silicon dioxide, Titanium dioxide",
author = "Mikhailov, {M. M.} and Yuryev, {S. A.} and Remnev, {G. E.} and Sazonov, {R. V.} and Vlasov, {V. A.} and Kholodnaya, {G. E.}",
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T1 - The study of processes affecting the radiation resistance of TiO2 powders after heating and modification with SiO2 nanoparticles

AU - Mikhailov, M. M.

AU - Yuryev, S. A.

AU - Remnev, G. E.

AU - Sazonov, R. V.

AU - Vlasov, V. A.

AU - Kholodnaya, G. E.

PY - 2017/4/26

Y1 - 2017/4/26

N2 - We have investigated the processes occurring within titanium dioxide powders heated and modified by silicon dioxide nanoparticles at 150, 400, and 800 °C. It has been figured out that the mentioned modification stipulates the increase in the powders’ radiation resistance. While investigating, we employed methods of the near-/mid-infrared regions spectrophotometry, derivatography, and mass spectrometry. The research results show that the increase in the radiation resistance at the heating is stipulated by a number of factors, namely (1) the desorption of the physically/chemically bound gases, (2) upfilling of the released bonds with the oxygen molecules, and (3) the improvement of titanium dioxide stoichiometry on the surface. The after-modification radiation resistance increases excessively (as opposed to the heating) due to the fact that the electron–hole pairs relaxate on the nanoparticles, which precipitate onto the surface of titanium dioxide powder.

AB - We have investigated the processes occurring within titanium dioxide powders heated and modified by silicon dioxide nanoparticles at 150, 400, and 800 °C. It has been figured out that the mentioned modification stipulates the increase in the powders’ radiation resistance. While investigating, we employed methods of the near-/mid-infrared regions spectrophotometry, derivatography, and mass spectrometry. The research results show that the increase in the radiation resistance at the heating is stipulated by a number of factors, namely (1) the desorption of the physically/chemically bound gases, (2) upfilling of the released bonds with the oxygen molecules, and (3) the improvement of titanium dioxide stoichiometry on the surface. The after-modification radiation resistance increases excessively (as opposed to the heating) due to the fact that the electron–hole pairs relaxate on the nanoparticles, which precipitate onto the surface of titanium dioxide powder.

KW - Electron irradiation

KW - Heating

KW - Modification

KW - Silicon dioxide

KW - Titanium dioxide

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