Theoretical analysis of solid oxide fuel cells with two-layer, composite electrolytes; Electrolyte stability
- Dept. of Materials Science and Engineering, Univ. of Utah, Salt Lake City, UT (US)
In this paper theoretical analysis of solid oxide fuel cells (SOFCs) using two-layer, composite electrolytes consisting of a solid electrolyte of a significantly higher conductivity compared to zirconia (such as ceria or bismuth oxide) with a thin layer of zirconia or thoria on the fuel side is presented. Electrochemical transport in the two layer, composite electrolytes is examined by taking both ionic and electronic fluxes into account. Similar to most electrochemical transport phenomena, it is assumed that local equilibrium prevails. An equivalent circuit approach is used to estimate the partial pressure of oxygen at the interface. It is shown that thermodynamic stability of the electrolyte (ceria or bismuth oxide) depends upon the transport characteristics of the composite electrolyte, in particular the electronic conductivity of the air-side part of the electrolyte. For example, the greater the electronic conductivity of the air-side part of the electrolyte, the greater is the interface partial pressure of oxygen and the greater is the thermodynamic stability. The analysis shows that it would be advantageous to use composite electrolytes instead of all-zirconia electrolytes, thus making low-temperature ({approximately}600-800{degrees}C) SOFCs feasible. Implications of the analysis from the standpoint of the desired characteristics of SOFC components are discussed.
- OSTI ID:
- 5778107
- Journal Information:
- Journal of the Electrochemical Society; (United States), Vol. 138:5; ISSN 0013-4651
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
ELECTROLYTES
MATERIALS TESTING
SOLID ELECTROLYTE FUEL CELLS
ELECTROCHEMISTRY
PERFORMANCE TESTING
THORIUM OXIDES
THIN FILMS
ZIRCONIUM OXIDES
BISMUTH OXIDES
CERIUM OXIDES
COMPOSITE MATERIALS
ACTINIDE COMPOUNDS
BISMUTH COMPOUNDS
CERIUM COMPOUNDS
CHALCOGENIDES
CHEMISTRY
DIRECT ENERGY CONVERTERS
ELECTROCHEMICAL CELLS
FILMS
FUEL CELLS
MATERIALS
OXIDES
OXYGEN COMPOUNDS
RARE EARTH COMPOUNDS
TESTING
THORIUM COMPOUNDS
TRANSITION ELEMENT COMPOUNDS
ZIRCONIUM COMPOUNDS
300505* - Fuel Cells- Electrochemistry
Mass Transfer & Thermodynamics
300502 - Fuel Cells- Performance & Testing
300503 - Fuel Cells- Materials
Components
& Auxiliaries