Synthesis and characterization of (68-x) CuO – xV2O5 – 32TeO2 (x = 0–68 mol%) and (35-x) CuO – xV2O5 – 65TeO2 (x = 0–35 mol%) glasses: Conduction mechanism, structure and EPR study

In this work, two series of glasses, i.e. (68-x) CuO – xV2O5 – 32TeO2 (x = 0–68 mol%, Te32 series) and (35-x) CuO – xV2O5 – 65TeO2 (x = 0–35 mol%, Te65 series), were synthesized by the melt-quenching method and subjected to physical, thermal and electrical characterization. Their vitreous nature was...

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Bibliographic Details
Published in:Materials chemistry and physics 2021-07, Vol.266, p.124488, Article 124488
Main Authors: Mugoni, Consuelo, Rosa, Roberto, Giovanardi, Roberto, Affatigato, Mario, Gualtieri, Magdalena Lassinantti, Siligardi, Cristina, Andronenko, Sergey I., Misra, Sushil Kumar
Format: Article
Language:English
Subjects:
Conductive glasses
Copper
Electrical properties
Electron paramagnetic resonance
Electron transfer
Glass transition temperature
Melt quenching method
Metal oxide glasses
Raman spectroscopy
Spectrum analysis
Thermodynamic properties
Valence
Vanadium-tellurite glasses
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Summary:In this work, two series of glasses, i.e. (68-x) CuO – xV2O5 – 32TeO2 (x = 0–68 mol%, Te32 series) and (35-x) CuO – xV2O5 – 65TeO2 (x = 0–35 mol%, Te65 series), were synthesized by the melt-quenching method and subjected to physical, thermal and electrical characterization. Their vitreous nature was confirmed by X-Ray diffraction and differential scanning calorimetry, while their structural units were determined by Raman spectroscopy. CuO substitution by V2O5 led to a decrease in density and glass-transition temperature, together with a conductivity increase. Conduction mechanism was interpreted as mainly due to small polaron hopping from the lower (V4+) to the higher (V5+) vanadium valence states. Te32 glasses, possessing the highest electronic conductivities (ranging from 2 E−4 to 5 E−7 Ω−1 cm−1), were investigated by the Electron Paramagnetic Resonance technique, in order to more deeply analyze their structure-conductivity correlation. Particularly, the observed signals were determined to consist in a superposition of a first line due to paramagnetic Cu2+ ions and a second line due to exchange-coupled CuO clusters. Differences in the spectra were determined between samples with higher (i.e. 20-30 mol%) Cu2+ concentrations and samples with lower Cu2+ concentrations, suggesting they are located in different local environments. Finally, it was found that the Cu2+ ions are not involved in the process of electron transfer. [Display omitted] •Electronic conductive glass systems containing two TMOs were investigated.•Two series of CuO–V2O5–TeO2 glasses with 32 and 65 mol% of TeO2 were compared.•Conduction mechanism mainly due to small polaron hopping between vanadium ions.•Cu2+ ions are not involved in the conduction mechanism.•The 32 mol% TeO2 series was deepened by EPR since possessing higher conductivity.
ISSN:0254-0584
1879-3312
DOI:10.1016/j.matchemphys.2021.124488