Microstructural effects on the electrical behaviour of SrTi0.95Nb0.05O3+δ materials on changing from reducing to oxidising conditions
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[1] Yi-bing Cheng,et al. Phase formation and microstructural evolution of Ca α-sialon using different Si3N4 starting powders , 2000 .
[2] J. Labrincha,et al. Representations of impedance spectra of ceramics: Part II. spectra of polycrystalline srtio3 , 2000 .
[3] J. Labrincha,et al. Evaluation of SrTi1âyNbyO3+δ materials for gas sensors , 1999 .
[4] J. R. Jurado,et al. Electrochemical permeability of Sr0.7(Ti,Fe)O3−δ materials , 1999 .
[5] J. Maier,et al. Electrochemical Investigations of SrTiO3 Boundaries , 1997 .
[6] R. Moos,et al. ELECTRONIC TRANSPORT PROPERTIES OF SR1-XLAXTIO3 CERAMICS , 1996 .
[7] P. Slater,et al. Synthesis and electrical characterisation of the perovskite niobate-titanates, Sr1−x/2Ti1−xNbxO3−δ , 1996 .
[8] D. Sinclair,et al. Impedance and modulus spectroscopy of semiconducting BaTiO3 showing positive temperature coefficient of resistance , 1989 .
[9] Harry L. Tuller,et al. Defect Structure and Electrical Properties of Single‐Crystal Ba0.03Sr0.97TiO3 , 1988 .
[10] S. Neirman,et al. Dielectric properties of donor-doped polycrystalline SrTiO3 , 1982 .
[11] R. Sharma,et al. Nonstoichiometry in SrTiO3 , 1981 .
[12] R. Waser,et al. Grain Boundary Defect Chemistry of Acceptor‐Doped Titanates: Space Charge Layer Width , 1994 .
[13] John Crank,et al. The Mathematics Of Diffusion , 1956 .