Sr2−XLaXMgMoO6 and Sr2−XLaXMgNbO6 for Use as Sulfur-Tolerant Anodes Without a Buffer Layer

Sr2−XLaXMgMoO6 and Sr2−XLaXMgNbO6 for Use as Sulfur-Tolerant Anodes Without a Buffer Layer

The objective of this effort is to synthesize and characterize a series of lanthanum‐(La) doped Sr2MgMoO6 (SMMO) and La‐doped Sr2MgNbO6 (SMNO) anode materials which can be used in combination with lanthanum‐containing electrolytes to mitigate the effects of lanthanum poisoning in solid oxide fuel ce...

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Bibliographic Details
Published in:Journal of the American Ceramic Society Vol. 97; no. 11; pp. 3636 - 3642
Main Authors: Howell, Thomas G., Kuhnell, Cory P., Reitz, Thomas L., Eigenbrodt, Bryan C., Singh, Raj N.
Format: Journal Article
Language:English
Published: Blackwell Publishing Ltd 01-11-2014
Subjects:
Anodes
Buffer layers
Diffusion
Electrochemical analysis
Electrolytes
Electronics
Solid oxide fuel cells
Stability
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Summary:The objective of this effort is to synthesize and characterize a series of lanthanum‐(La) doped Sr2MgMoO6 (SMMO) and La‐doped Sr2MgNbO6 (SMNO) anode materials which can be used in combination with lanthanum‐containing electrolytes to mitigate the effects of lanthanum poisoning in solid oxide fuel cells (SOFCs). Currently, an La0.4Ce0.6O1.8 (LDC) buffer layer is used with many perovskite‐based anode materials to prevent La diffusion into the anode from the La0.8Sr0.2Ga0.8Mg0.2O2.8 (LSGM) electrolyte which can create a resistive La species that impedes electrochemical performance. The LDC buffer layer, with diminished electronic conductivity, adds an extra level of complexity in the SOFC manufacturing process. Further, this extraneous layer presents an added experimental challenge when assessing anode material performance. Overall electrochemical performance could be improved if the resistive buffer layer could be removed, thereby allowing the anode material to have direct contact with the electrolyte. To accomplish this, a new class of anode materials was synthesized with the goal of balancing “La” chemical potential between these neighboring materials. La‐doped SMMO and SMNO were prepared and studied. It was hypothesized that by incorporating La into the anode, the gradient of chemical activity between the anode and electrolyte would decrease, which would prevent La diffusion. These anode materials were synthesized via a sol–gel methodology and characterized with X‐ray diffraction to assess phase purity. The conductivity of the materials was analyzed in the presence of both H2 and 100 ppm H2S/H2 to determine the stability and performance of these materials during device operation. The stability experiments demonstrated that 40% La‐doped SMNO is stable in all pertinent environments while not reacting with the LSGM electrolyte.
Bibliography:ark:/67375/WNG-8GJ2149N-Q
istex:86D6875DEAF15B4FB4D25E84B96A3ACEA9BC7040
Oklahoma State University
ArticleID:JACE13208
National Science Foundation - No. 1233126
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0002-7820
1551-2916
DOI:10.1111/jace.13208