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Volume 17, Issue 5
  • ISSN: 2666-1454
  • E-ISSN: 2666-1462

Abstract

Background

Ceria (CeO) belongs to rare-earth series and due to its profitable properties, presents a wide commercial use such as catalysis, energy, biological, biomedical, and pharmaceutical. The features of the starting materials in the form of free powders influence notably the processing, formation, as well as characteristics of the final structures\bodies obtained by colloidal processing. This study aims to characterize CeO powders. The results obtained are worthwhile data to advance toward new rare-earth based materials for radiation dosimetry.

Methods

CeO powders were evaluated by the following techniques: PCS, SEM, XRD, FT-IR, EPR, IPC, and pycnometric density (ρ). The stability of particles in aqueous solvent was evaluated by zeta potential (ζ) determination.

Results

CeO powders exhibited cubic C-type form, F space group, a mean particle size (d) of 19.3 nm, and a pycnometric density (ρ) of 7.01g.cm-3. Based on the results of zeta potential determination, CeO powders exhibited high stability at pH 6.4 with ζ-value of |34.0|mV.

Conclusion

The evaluation of CeO powders was reported. The results presented and discussed in this study contribute to advance in the search of new rare-earth based materials for radiation dosimetry.

© 2024 Bentham Science Publishers
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2024-11-22

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/content/journals/cms/10.2174/2666145417666230823091126
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Characterization of Ceria Powders as a Continuous Search for New Rare-earth Based Materials for Radiation Dosimetry
Current Materials Science 17, 444 (2024); https://doi.org/10.2174/2666145417666230823091126
/content/journals/cms/10.2174/2666145417666230823091126
/content/journals/cms/10.2174/2666145417666230823091126
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  • Article Type:     Research Article
Keyword(s): CeO2 powders; ceramic processing; Ceria; nanoparticles; radiation dosimetry; rare-earths

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