Defect structure and electrical properties of LaSr sub(3)Fe sub(3)O sub(10- delta )

As a mixed conductor, LaSr sub(3)Fe sub(3)O sub(10- delta ) with triple layer perovskite intergrowth structure can be used as an oxygen separation membrane material and cathode material in solid oxide fuell cells. LaSr sub(3)Fe sub(3)O sub(10- delta ) was synthesized via citrate acid route. Iodine t...

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Bibliographic Details
Published in:Journal of rare earths 2010-04, Vol.28 (2), p.270-273
Main Authors: Zhang, Guoguang, Li, Qin, Cao, Jingqian, Cui, Mingjie
Format: Article
Language:English
Subjects:
Chemical diffusion
Coefficients
Conductors (devices)
Iodine
Mathematical models
Partial pressure
Rare earth metals
Resistivity
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Summary:As a mixed conductor, LaSr sub(3)Fe sub(3)O sub(10- delta ) with triple layer perovskite intergrowth structure can be used as an oxygen separation membrane material and cathode material in solid oxide fuell cells. LaSr sub(3)Fe sub(3)O sub(10- delta ) was synthesized via citrate acid route. Iodine titration method was used to determine the average valence of transition metal Fe and oxygen nonstoichiometry delta . Conductivities of LaSr sub(3)Fe sub(3)O sub(10-) delta were measured in the oxygen partial pressure range from 10 super(-2) x 10 super(5) to 1 x 10 super(5) Pa, by Ac four probe method. Seebeck coefficient measurement together with conductivity results indicated that LaSr sub(3)Fe sub(3)O sub(10-) delta is a p-type conductor. A linear relationship between the conductivity and logarithm of oxygen partial pressure was observed in the measurement. A defect model was introduced to explain the observed phenomena in the iodine titration, conductivity and Seebeck coefficient measurement. Electrical conductivity relaxation method was used to determine the oxygen chemical diffusion coefficient D sub(chem). The apparent activation energy of oxygen chemical diffusion was calculated to be 61.4 kJ/mol.
ISSN:1002-0721
DOI:10.1016/S1002-0721(09)60094-6