Electrical Conductivity and Chemical Diffusion Coefficient of Strontium-Doped Lanthanum Manganites

Electrical conductivity and chemical diffusion coefficient of Sr-doped lanthanum manganites, La1−xSrxMnO3±δ(x= 0.05 − 0.20), were measured by the dc four-probe technique and relaxation type experiments where a sudden change of oxygen chemical potential was imposed on the pre-equilibrated sample and...

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Veröffentlicht in:	Journal of Solid State Chemistry 1996-05, Vol.123 (2), p.382-390
Hauptverfasser:	Yasuda, Isamu, Hishinuma, Masakazu
Format:	Artikel
Sprache:	eng
Schlagworte:	Condensed matter: electronic structure, electrical, magnetic, and optical properties Condensed matter: structure, mechanical and thermal properties Conductivity phenomena in semiconductors and insulators CRYSTAL DOPING DIFFUSION Diffusion in solids Diffusion of other defects ELECTRIC CONDUCTIVITY Electronic transport in condensed matter Exact sciences and technology LANTHANUM OXIDES Low-field transport and mobility piezoresistance MANGANESE OXIDES MATERIALS SCIENCE Physics STOICHIOMETRY STRONTIUM OXIDES Transport properties of condensed matter (nonelectronic) VACANCIES
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container_title	Journal of Solid State Chemistry
container_volume	123
creator	Yasuda, Isamu Hishinuma, Masakazu
description	Electrical conductivity and chemical diffusion coefficient of Sr-doped lanthanum manganites, La1−xSrxMnO3±δ(x= 0.05 − 0.20), were measured by the dc four-probe technique and relaxation type experiments where a sudden change of oxygen chemical potential was imposed on the pre-equilibrated sample and the change of electrical conductivity was followed as a function of elapsed time. A defect model is proposed to elucidate the oxygen partial pressure dependence of the measured conductivity and the reported oxygen nonstoichiometry. The transient conductivity behavior after an abrupt change of oxygen partial pressure was successfully described by a diffusion model with consideration of partial control by surface reaction. The determined chemical diffusion coefficients, of the order of 10−5to 10−4cm2s−1at 1000°C, increased with decreased oxygen partial pressure due to the thermodynamic enhancement effect. Using the enhancement factor estimated by combination of the proposed defect model and the ambipolar diffusion theory, the oxygen vacancy diffusion coefficients were derived. High vacancy diffusivity comparable to that of Fe- or Co-based perovskites predicts fast oxide ion diffusion under conditions where the manganites show oxygen deficient type non-stoichiometry.
doi_str_mv	10.1006/jssc.1996.0193
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A defect model is proposed to elucidate the oxygen partial pressure dependence of the measured conductivity and the reported oxygen nonstoichiometry. The transient conductivity behavior after an abrupt change of oxygen partial pressure was successfully described by a diffusion model with consideration of partial control by surface reaction. The determined chemical diffusion coefficients, of the order of 10−5to 10−4cm2s−1at 1000°C, increased with decreased oxygen partial pressure due to the thermodynamic enhancement effect. Using the enhancement factor estimated by combination of the proposed defect model and the ambipolar diffusion theory, the oxygen vacancy diffusion coefficients were derived. 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A defect model is proposed to elucidate the oxygen partial pressure dependence of the measured conductivity and the reported oxygen nonstoichiometry. The transient conductivity behavior after an abrupt change of oxygen partial pressure was successfully described by a diffusion model with consideration of partial control by surface reaction. The determined chemical diffusion coefficients, of the order of 10−5to 10−4cm2s−1at 1000°C, increased with decreased oxygen partial pressure due to the thermodynamic enhancement effect. Using the enhancement factor estimated by combination of the proposed defect model and the ambipolar diffusion theory, the oxygen vacancy diffusion coefficients were derived. 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A defect model is proposed to elucidate the oxygen partial pressure dependence of the measured conductivity and the reported oxygen nonstoichiometry. The transient conductivity behavior after an abrupt change of oxygen partial pressure was successfully described by a diffusion model with consideration of partial control by surface reaction. The determined chemical diffusion coefficients, of the order of 10−5to 10−4cm2s−1at 1000°C, increased with decreased oxygen partial pressure due to the thermodynamic enhancement effect. Using the enhancement factor estimated by combination of the proposed defect model and the ambipolar diffusion theory, the oxygen vacancy diffusion coefficients were derived. High vacancy diffusivity comparable to that of Fe- or Co-based perovskites predicts fast oxide ion diffusion under conditions where the manganites show oxygen deficient type non-stoichiometry.</abstract><cop>San Diego, CA</cop><pub>Elsevier Inc</pub><doi>10.1006/jssc.1996.0193</doi><tpages>9</tpages></addata></record>
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subjects	Condensed matter: electronic structure, electrical, magnetic, and optical properties Condensed matter: structure, mechanical and thermal properties Conductivity phenomena in semiconductors and insulators CRYSTAL DOPING DIFFUSION Diffusion in solids Diffusion of other defects ELECTRIC CONDUCTIVITY Electronic transport in condensed matter Exact sciences and technology LANTHANUM OXIDES Low-field transport and mobility piezoresistance MANGANESE OXIDES MATERIALS SCIENCE Physics STOICHIOMETRY STRONTIUM OXIDES Transport properties of condensed matter (nonelectronic) VACANCIES
title	Electrical Conductivity and Chemical Diffusion Coefficient of Strontium-Doped Lanthanum Manganites
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