Enhancement of polaron-hopping-based a.c. conduction in semiconducting STS (Se–Te–Sn) glass by silver incorporation
Abstract
In the present work, we have synthesized novel Se78−xAgxTe20Sn2 (0 ≤ x ≤ 6) semiconducting glasses for improving thermally activated a.c. conduction in STS glass (x = 0). The results of the experimental analysis of thermally activated a.c. conduction have been reported in terms of frequency and temperature of Se78−xAgxTe20Sn2 (0 ≤ x ≤ 6) glasses. The frequency dependent experimental data of a.c. conductivity σac show that σac follows the Jonscher universal power law. Variation of a.c. conductivity with temperature obeys the Arrhenius relation. Further analysis confirms that the density of defect states can be determined on the basis of a correlated barrier hopping model using the frequency/temperature dependence of a.c. conductivity σac (T,ω). The analysis of composition dependence of various electric parameters like potential barrier height Wm, hopping distances Rmin and Rω, dielectric constant (ε′) and the density of defect states N shows that hopping conduction is improved after silver incorporation into the parent glass. This is explained in terms of a dipolar model by considering the dipoles of Ag+ ions with negatively charged defect states.