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authors |
Yaremchenko, AA; Macias, J; Kovalevsky, AV; Arias-Serrano, BI; Frade, JR |
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nationality |
International |
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journal |
JOURNAL OF POWER SOURCES |
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author keywords |
Perovskite; Strontium titanate; Electrical conductivity; Thermal expansion; Fuel electrode; Interconnect |
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keywords |
DOPED STRONTIUM-TITANATE; EFFECTIVE IONIC-RADII; HIGH-TEMPERATURE; FUEL-CELLS; DEFECT CHEMISTRY; PHASE-TRANSITION; ANODE MATERIALS; CERAMICS; BEHAVIOR; LA |
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abstract |
The present work aims to evaluate relevant effects of the size of substituting rare-earth cation on electrical conductivity and thermal expansion of donor-doped SrTiO3 as ceramic components of electrochemical solid electrolyte cells. A series of strontium titanate-based ceramics with a moderate doping level and different cation stoichiometry, Sr(0.90)Ln(0.10)TiO(3 +/-delta) and Sr(0.85)Ln(0.10)TiO(3 +/-delta) (Ln = La-Yb), are prepared under identical conditions with the final reductive treatment in 10%H-2-N-2 atmosphere at 1500 degrees C for 10 h. The solubility of rare-earth cations in the strontium sublattice of perovskite-type SrTiO3 is found to decrease with reducing ionic radius leading to a segregation of secondary pyrochlore-type Ln(2)Ti(2)O(7) phase in the case of smaller rare-earth cations (Ln = Dy-Yb). The results of electrical, dilatometric and thermogravimetric studies suggest that the size of donor Ln(3+) cation and cation stoichiometry have no evident impact on the electrical conductivity or thermal expansion behavior as long as the content of Ln(3+) is within the solubility limits. All reduced donor-doped titanate ceramics (except Yb-doped) show a similar level of electrical conductivity, 100-155 S cm(-1) at 800 degrees C, determined by the content of Ln(3+) in the strontium sublattice, and moderate thermal expansion coefficients, 11.9-12.1 ppm K-1 at 25-1100 degrees C, compatible with that of conventional solid electrolytes. |
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publisher |
ELSEVIER |
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issn |
0378-7753 |
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isbn |
1873-2755 |
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year published |
2020 |
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volume |
474 |
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digital object identifier (doi) |
10.1016/j.jpowsour.2020.228531 |
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web of science category |
Chemistry, Physical; Electrochemistry; Energy & Fuels; Materials Science, Multidisciplinary |
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subject category |
Chemistry; Electrochemistry; Energy & Fuels; Materials Science |
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unique article identifier |
WOS:000571474400005
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