Oxygen Nonstoichiometry and Ion-Electron Transport in SrFe0.9M0.1O3-δ (M=Cr, Ti, Al)

Mikhail V. Patrakeev; I.A. Leonidov; V.L. Kozhevnikov; Vladislav V. Kharton

doi:10.4028/www.scientific.net/MSF.514-516.382

Paper Titles

Effect of Wheel Speed and Boron Content on Microstructure and Crystallographic Texture of Boron Substituted Sm-Co Melt Spun Ribbons
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Local Vibrations of Substitutional Carbon in SiGe Alloys
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Chromatic Dispersion in Ge-Doped SiO₂-Based Single Mode Fibres due to Temperature Dependence of the Ultraviolet Absorption: Numerical and Experimental Results
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Oxygen Evolution on Perovskite-Type Cobaltite Anodes: An Assessment of Materials Science-Related Aspects
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Oxygen Nonstoichiometry and Ion-Electron Transport in SrFe_0.9M_0.1O_3-δ (M=Cr, Ti, Al)
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Transport Properties and Thermal Expansion of SrCe(Y)O_3-δ Ceramics
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Conductivity of La- and Pr- Doped Bi₄V₂O₁₁
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Defect Formation in La₂Ni(M)O_4+δ (M= Co, Cu): Modelling and Coulometric Titration Study
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Mixed Conductivity of Ce- and Nb-Substituted (La, Sr)FeO_3-δ
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Oxygen Nonstoichiometry and Ion-Electron Transport in SrFe_0.9M_0.1O_3-δ (M=Cr, Ti, Al)

Abstract:

The total conductivity and oxygen deficiency of partially substituted strontium ferrite, SrFe0.9M0.1O3-δ (M=Cr, Ti, Al), at 700-950°C were measured depending on oxygen partial pressure varying in ranges 10-19-0.5 and 10-5-0.5 atm. The partial contributions of n- and p-type electronic charge carriers and oxygen ions to the electrical transport were determined analyzing the total conductivity vs. oxygen pressure dependencies. Additions of all dopants studied in this work are found to extend the cubic perovskite phase stability range and to improve oxygen transport in the intermediate-temperature range. The behavior of hole mobility suggests a polaron conduction mechanism. Doping with aluminum has a weak influence on the mobility level, while the incorporation of Cr and Ti cations into the ferrite lattice decreases hole mobility up to four times.