The study of high-dc electric field effect on the conduction of V sub(2)O sub(5)-Sb-TeO sub(2) glasses and the applicability of an electrothermal model

Ternary (60-x)V sub(2)O sub(5)-xSb-40TeO sub(2) oxide glasses (with 0 less than or equal to x less than or equal to 15 in mol%), prepared using the usual melt quenching method, were investigated electrically (at the presence of high-dc electric fields) within the temperature range of 298-375.3 K at...

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Bibliographic Details
Published in:Journal of materials science 2015-03, Vol.50 (6), p.2554-2560
Main Authors: Souri, Dariush, Ghasemi, Raziyeh, Shiravand, Mahdiyeh
Format: Article
Language:English
Subjects:
Deviation
Electric fields
Electrodes
Filaments
Glass
Mathematical models
Ohm's Law
Switching
Threshold voltage
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Summary:Ternary (60-x)V sub(2)O sub(5)-xSb-40TeO sub(2) oxide glasses (with 0 less than or equal to x less than or equal to 15 in mol%), prepared using the usual melt quenching method, were investigated electrically (at the presence of high-dc electric fields) within the temperature range of 298-375.3 K at different electrode distances. The current-voltage characteristics show increasing deviations from Ohm's law at electric fields of about >10 super(3) V/cm. This behavior can be attributed to the Pool-Frenkel effect, which usually occurs at the mentioned electric fields. At higher fields, switching (from low conduction state to higher conduction state) or negative resistance phenomena were observed at a threshold voltage (V sub(th)). The threshold voltage for beginning the switching/negative resistance shows a decreasing trend with increasing in temperature and also with decreasing of electrode distance. An electrothermal model (based on the Joule heating effect in the current filament) is proposed to interpret the observed electrical properties. Also, the lowering factor of potential barrier ( beta sub(PF)) in Pool-Frenkel effect, heat dissipation factor, and electrical activation energy of the present samples were determined. In each sample, the increase of beta sub(PF) with temperature can explain the phonon-assisted hopping conduction.
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-015-8815-5