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The kinetics of electrochemical reactions on high temperature fuel cell electrodes

The rates of electrochemical reactions relevant for use in high-temperature solid oxide fuel cells (SOFC) has been investigated as a function of electrode potential, temperature and composition of the gas mixture. From Arrhenius plots, apparent activation energies, E a, and apparent pre-exponential...

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Bibliographic Details
Published in:Journal of power sources 1994-04, Vol.49 (1), p.257-270
Main Authors: Divisek, J., de Haart, L.G.J., Holtappels, P., Lennartz, T., Malléner, W., Stimming, U., Wippermann, K.
Format: Article
Language:English
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Summary:The rates of electrochemical reactions relevant for use in high-temperature solid oxide fuel cells (SOFC) has been investigated as a function of electrode potential, temperature and composition of the gas mixture. From Arrhenius plots, apparent activation energies, E a, and apparent pre-exponential factors, A, were calculated for the oxygen-reduction and oxygen-evolution reactions at La 0.84Sr 0.16MnO 3 cathodes. At low overpotentials (|η| ⩽ 0.2 V), both apparent activation energies and apparent pre-exponential factors are much higher in the temperature range T = 800−1000 °C ( E a ≈ 160−210 kJ/mol, log A ≈ 6−9) compared with those in the range T = 500−800 °C ( E a ≈ 80−110 kJ/mol, log A ≈ 2−4). For oxygen reduction, reaction orders of z e = 1 at p O 2 > 0.2 bar and z e = 0.5 at p O 2 < 0.2 bar were obtained. These values may be related to either oxygen adsorbed as molecules or atoms as the reacting species. From impedance spectroscopy, it follows that the rate of the oxygen-exchange reaction is determined not only by charge transfer, but also by another process, possibly the adsorption or surface diffusion of intermediates. For the nickel zirconia cermet anode fabricated by wet powder spraying (WPS), an increase in sintering temperature to 1400 °C results in an increase in current density. A current density of 0.27 A cm −2 at an overvoltage of 0.1 V may be achieved. From Arrhenius plots, an energy of activation of 130 ± 10 kJ mol −1 was determined.
ISSN:0378-7753
1873-2755
DOI:10.1016/0378-7753(93)01817-2