CO2 corrosion and recovery of perovskite-type BaCo1−x−yFexNbyO3−δ membranes

Corrosion in CO2 and recovery in CO2-free gas of BaCo1−x−yFexNbyO3−δ (x=0.2–0.8, y=0.1–0.5) perovskite membranes were studied at 800–1000°C for potential application in oxyfuel combustion. The oxygen permeation fluxes decreased during exposure to CO2, which became less pronounced with increasing con...

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Bibliographic Details
Published inJournal of membrane science Vol. 437; pp. 49 - 56
Main Authors Yi, Jianxin, Weirich, Thomas E., Schroeder, Michael
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 15.06.2013
Elsevier
Subjects
annealing
artificial membranes
barium
carbon dioxide
Chemistry
cobalt
Colloidal state and disperse state
combustion
corrosion
Exact sciences and technology
General and physical chemistry
iron
Membranes
microstructure
oxygen
permeability
X-ray diffraction
Ceramic membrane
Perovskite
Oxygen
Separation
Corrosion
Perovskite type compound
Mixed conducting
Oxygen separation
CO
Recovery
Inorganic membrane
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Summary:Corrosion in CO2 and recovery in CO2-free gas of BaCo1−x−yFexNbyO3−δ (x=0.2–0.8, y=0.1–0.5) perovskite membranes were studied at 800–1000°C for potential application in oxyfuel combustion. The oxygen permeation fluxes decreased during exposure to CO2, which became less pronounced with increasing content of Fe and/or Nb. No significant degradation was observed for the cobalt-free composition with high Fe/Nb contents, BaFe0.55Nb0.45O3−δ. A combined analysis of XRD, IR, TGA, and SEM-EDS revealed that degradation in both the phase composition and microstructure with carbonate formation occurred during annealing in CO2, particularly for samples of low Fe/Nb content. The enhanced CO2 resistance of the perovskite due to Fe/Nb doping was found to accord with an increasing average metal–oxygen bonding. The loss of oxygen permeability caused by CO2 was rapidly recovered by switching the sweep gas back to a CO2-free inert gas. Decomposition of carbonate and formation of Ba(Co, Fe)xOy phases took place during the recovery both on the surface and in the decomposed zone. However, the original perovskite phase and dense grain structure was not regenerated. ► Structure and oxygen permeability of BaCo1−x−yFexNbyO3−δ degraded in CO2. ► The degradation in CO2 mitigated with increasing Fe/Nb contents. ► Loss of oxygen permeability caused by CO2 can be recovered. ► Original structure was not regenerated. ► CO2 resistance is connected with the average metal–oxygen bonding.
Bibliography:http://dx.doi.org/10.1016/j.memsci.2013.02.049
ISSN:0376-7388
1873-3123
DOI:10.1016/j.memsci.2013.02.049