Litcius/Paper detail

Mechanism of hopping conduction in Be–Fe–Al–Te–O semiconducting glasses and glass–ceramics

Natalia Anna Wójcik, Nagia S. Tagiara, Doris Möncke, E. I. Kamitsos, Sharafat Ali, Jacek Ryl, R.J. Barczyński

2022Journal of Materials Science17 citationsDOIOpen Access PDF

Abstract

Abstract Electrical properties of beryllium-alumino-tellurite glasses and glass–ceramics doped with iron ions were studied using impedance spectroscopy. The conductivity was measured over a wide frequency range from 10 mHz to 1 MHz and the temperature range from 213 to 473 K. The D.C. conductivity values showed a correlation with the Fe-ion concentration and ratio of iron ions on different valence states in the samples. On the basis of Jonscher universal dielectric response the temperature dependence of conductivity parameters were determined and compared to theoretical models collected by Elliott. In glasses, the conduction process was found to be due to the overlap polaron tunneling while in glass–ceramics the quantum mechanical tunneling between semiconducting crystallites of iron oxides is proposed. The D.C. conductivity was found not to follow Arrhenius relation. The Schnakenberg model was used to analyze the conductivity behavior and the polaron hopping energy and disorder energy were estimated. Additionally, the correlation between alumina dissolution and basicity of the melts was observed.

Topics & Concepts

PolaronMaterials scienceConductivityActivation energyArrhenius equationIonValence (chemistry)CeramicDielectricAmorphous solidQuantum tunnellingCrystalliteElectrical resistivity and conductivityThermal conductionCondensed matter physicsAtmospheric temperature rangeVariable-range hoppingDopingAnalytical Chemistry (journal)Physical chemistryThermodynamicsComposite materialElectronChemistryMetallurgyCrystallographyEngineeringOptoelectronicsChromatographyOrganic chemistryElectrical engineeringPhysicsQuantum mechanicsGlass properties and applicationsNuclear materials and radiation effectsMicrowave Dielectric Ceramics Synthesis