Understanding the electrochemical behaviour of LSM-based SOFC cathodes. Part I — Experimental and electrochemical

The enhancement of electroactivity and stability of solid oxide fuel cell (SOFC) cathodes is an open issue for the scientific community. Only a careful experimental approach, coupled with advanced modelling and interpretation, allows for a comprehensive understanding and optimization of materials no...

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Bibliographic Details
Published inSolid state ionics Vol. 301; pp. 106 - 115
Main Authors Carpanese, M.P., Clematis, D., Bertei, A., Giuliano, A., Sanson, A., Mercadelli, E., Nicolella, C., Barbucci, A.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.03.2017
Subjects
Impedance spectroscopy
LSM
Overpotential
Oxygen reduction reaction
Oxygen surface diffusion
YSZ
CE
GI
LSM
Oxygen surface diffusion
Overpotential
Impedance spectroscopy
ORR
WE
RE
Oxygen reduction reaction
CPE
2-PB
3-PB
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Summary:The enhancement of electroactivity and stability of solid oxide fuel cell (SOFC) cathodes is an open issue for the scientific community. Only a careful experimental approach, coupled with advanced modelling and interpretation, allows for a comprehensive understanding and optimization of materials not completely exploited, such as strontium-doped lanthanum manganite (LSM). This paper, as first part of a couple of articles, presents experimental measurements of porous LSM cathodes and gives an interpretation of the oxygen reduction reaction (ORR) mechanism. The experimental section takes into account the effect of cell geometry and different electrode microstructures resulting from sintering the cathodes at different temperatures. Electrodes are tested with electrochemical impedance spectroscopy (EIS) in three-electrode configuration and the influence of cathodic dc bias, oxygen partial pressure and temperature is analysed. The effects of dc overpotential on the processes are remarkable and a particular attention is dedicated to this parameter. The analysis of experimental data with equivalent circuits identifies a critical overpotential between 0.15 and 0.2V. Around this value the system undergoes a modification in the ORR mechanism and a new reaction path is identified. Analogous conclusions are achieved in the second paper by using a detailed mechanistic modelling approach. [Display omitted] •Studied the effects of cathodic overpotential and microstructure in LSM cathodes•The microstructure matters at low bias while impedances level off at high bias•Identified charge-transfer at high frequency and transport process at low frequency•Transition from surface path to bulk path at 0.2V identified with equivalent circuits•Verified the geometric requirements to correctly measure impedance under bias
ISSN:0167-2738
1872-7689
DOI:10.1016/j.ssi.2017.01.007