Thermal stability of modified chromium dioxide nanopowders with various magnetic properties obtained by hydrothermal route

Thermal decomposition of hydrothermal micro- and nano-sized CrO 2 powders obtained at the presence of nuclei with different structures (Mo + Sb, Te + Sn) and an iron dopant (Te + Sn + Fe) was studied by thermal analysis (DTG–DSC), XRD, SEM, VSM methods, and SSA estimation. It has been found that the...

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Bibliographic Details
Published in:Journal of thermal analysis and calorimetry 2017-04, Vol.128 (1), p.71-78
Main Authors: Arkhipov, D. I., Bobrysheva, N. P., Dzidziguri, E. L., Osmolowsky, M. G., Osmolovskaya, O. M.
Format: Article
Language:English
Subjects:
Analysis
Analytical Chemistry
Antimony
Chemistry
Chemistry and Materials Science
Chromium (Metal)
Chromium dioxide
Chromium oxides
Decomposition
Dioxides
Inorganic Chemistry
Iron
Lattice parameters
Magnetic properties
Measurement Science and Instrumentation
Oxidation
Physical Chemistry
Polymer Sciences
Shell stability
Solid solutions
Surface layers
Thermal analysis
Thermal decomposition
Thermal stability
Tin
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Summary:Thermal decomposition of hydrothermal micro- and nano-sized CrO 2 powders obtained at the presence of nuclei with different structures (Mo + Sb, Te + Sn) and an iron dopant (Te + Sn + Fe) was studied by thermal analysis (DTG–DSC), XRD, SEM, VSM methods, and SSA estimation. It has been found that the decomposition of chromium dioxide happens with formation of CrO 1.5 at 450–540 °C, no changes in the lattice parameters were observed. The temperature of the process for nano-sized CrO 2 samples is 100 °C lower than for micro-sized sample. The decomposition of nanopowders occurs in two stages with DTG and DSC peaks at about 470 and 500 °C correspondingly. The particles under study consist of a CrO 2 core and a CrOOH shell, so the sample transformation begins from the shell oxidation resulting in the CrO 2 surface layer formation. The first peak corresponds to the decomposition of such layer to Cr 2 O 3 , and the second—to the core transformation which occurs later. For the iron-containing powders, the additional endoeffect and mass loss has been found at 550 °C, which is determined by presence of a Fe x Cr 1−x O 2 solid solution mainly located in the particle shell. The shift toward lower temperatures for nano-sized samples decomposition peak and the observed peak splitting indicate an impact of the dimensional effect on powder thermal stability. Obtained data show that nanopowders are highly stable up to 200 °C and can be used for magnetoelectronic devices.
ISSN:1388-6150
1588-2926
DOI:10.1007/s10973-016-5919-3