2019
DOI: 10.1016/j.vacuum.2019.02.029
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Study of phase transformations, structural, corrosion properties and cytotoxicity of magnetite-based nanoparticles

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Cited by 36 publications
(24 citation statements)
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“…[49,50] The phase transition from maghemite to hematite is usually observed at temperatures in the range of 300-650°C, depending on duration of heating, size, and crystal face of the particles and the method of sample preparation. [49,51,52] In the present study maghemite was not detected in the samples by Raman spectroscopy or XRD. It might argue for the firing temperature exceeded 650°C.…”
Section: Discussioncontrasting
confidence: 55%
“…[49,50] The phase transition from maghemite to hematite is usually observed at temperatures in the range of 300-650°C, depending on duration of heating, size, and crystal face of the particles and the method of sample preparation. [49,51,52] In the present study maghemite was not detected in the samples by Raman spectroscopy or XRD. It might argue for the firing temperature exceeded 650°C.…”
Section: Discussioncontrasting
confidence: 55%
“…As can be seen from the data presented for the initial nanostructures, broadening of diffraction peaks was observed, and two low-intensity peaks with Miller indices (200) and (220) are present, which indicates the presence of crystallites oriented in these directions in the structure. The asymmetric broadened shape of diffraction peaks for the initial nanotubes indicates the influence of both the size factor and the deformation factor on the change in structural properties [49,50]. For irradiated samples, a change in the intensities of diffraction maxima was observed with a complete dominance of the (111) diffraction maximum at an irradiation doses of 300 kGy and higher, while the intensity of diffraction maxima (200) and (220) for irradiated samples with a dose above 300 kGy is comparable with the background intensity radiation.…”
Section: Experimental Partmentioning
confidence: 99%
“…Despite the simplicity and efficiency of the application of the mechanical chemical method of synthesis to obtain perovskite-like structures, this method does not allow to obtain particles of nanoscale diameter with clearly controlled phase and stoichiometric compositions. One way to obtain such particles is to combine methods of chemical synthesis with subsequent thermal annealing of the nanoparticles obtained [38,39].…”
Section: Introductionmentioning
confidence: 99%