Electrochemical oxygen separation and compression using planar, cosintered ceramics

Cosintered, planar electrochemical devices were used to separate and compress oxygen at pressures as high as 2 MPa. Thin samaria-doped ceria electrolytes (CSO) were mechanically supported by porous electrodes and dense microchannel layers. Composite electrodes, comprised of CSO and La 1 − x Sr x Co...

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Bibliographic Details
Published in:Solid state ionics 2008-05, Vol.179 (11), p.442-450
Main Authors: Hutchings, Kent N., Bai, Jie, Cutler, Raymond A., Wilson, Merrill A., Taylor, Dale M.
Format: Article
Language:English
Subjects:
Electrochemical compression
Ionic conductivity
Oxygen separation
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Summary:Cosintered, planar electrochemical devices were used to separate and compress oxygen at pressures as high as 2 MPa. Thin samaria-doped ceria electrolytes (CSO) were mechanically supported by porous electrodes and dense microchannel layers. Composite electrodes, comprised of CSO and La 1 − x Sr x Co 0.2Fe 0.8O 3 − δ (LSCF) particles, were used for cathodic and anodic reactions. The incoming air and the separated oxygen were manifolded through microchannel layers composed of La 1 − y Ca y MnO 3 (LCM), a dense electrically conductive ceramic. Multiple green ceramic tape layers were featured by laser cutting before lamination. The laminated structure was cosintered to produce a functional microchanneled electrochemical device or couple suitable for electrically driven oxygen separation at temperatures > 600 °C. Multiple couples were assembled into stacks and connected electrically in series to generate the oxygen flow desired. The high chemical expansion of the electrodes resulted in microcracking, which facilitated the operation of this planar device without damage to the electrolyte. The thermal expansion of the LCM can be tailored to eliminate residual tensile stress in the electrolyte. Fabrication challenges include the different initial sintering temperatures and varying sintering rates of the materials. Good bonding between layers during cosintering enables the device to withstand internal oxygen pressures high enough to be used for many applications requiring pressurized high-purity oxygen; without the aid of an auxiliary mechanical endload.
ISSN:0167-2738
1872-7689
DOI:10.1016/j.ssi.2008.02.058