TY - JOUR
T1 - Reaction of hydrogen/water mixtures on nickel-zirconia cermet electrodes. I. DC polarization characteristics
AU - Holtappels, P.
AU - De Haart, L. G.J.
AU - Stimming, U.
PY - 1999/5
Y1 - 1999/5
N2 - The reaction of hydrogen/water mixtures on nickel-zirconia cermet electrodes has been investigated as a function of potential and temperature at three different partial pressures of the reactants. Apparent kinetic parameters, namely, reaction orders, activation enthalpies, and pre-exponential factors, were determined as a function of potential in low-temperature (725-845 °C) and high-temperature (845-950 °C) regions for both the hydrogen oxidation and the hydrogen evolution reactions. In the low-temperature region, the charge-transfer coefficient, αa, calculated according to absolute rate theory was 0.7, independent of temperature. The apparent reaction order of the hydrogen oxidation reaction is in the region of 0.5 at 725 °C, from which we conclude that at low temperatures, charge transfer involving atomically adsorbed hydrogen species determines the rate of this reaction. The results for the hydrogen oxidation reaction at temperatures above 845 °C as well as for the hydrogen evolution reaction are not consistent with a charge-transfer-controlled electrode reaction. Adsorption and chemical reaction between adsorbed species are considered to be dominant for the hydrogen oxidation reaction at temperatures above 845 °C and the hydrogen evolution reaction over the entire temperature range studied.
AB - The reaction of hydrogen/water mixtures on nickel-zirconia cermet electrodes has been investigated as a function of potential and temperature at three different partial pressures of the reactants. Apparent kinetic parameters, namely, reaction orders, activation enthalpies, and pre-exponential factors, were determined as a function of potential in low-temperature (725-845 °C) and high-temperature (845-950 °C) regions for both the hydrogen oxidation and the hydrogen evolution reactions. In the low-temperature region, the charge-transfer coefficient, αa, calculated according to absolute rate theory was 0.7, independent of temperature. The apparent reaction order of the hydrogen oxidation reaction is in the region of 0.5 at 725 °C, from which we conclude that at low temperatures, charge transfer involving atomically adsorbed hydrogen species determines the rate of this reaction. The results for the hydrogen oxidation reaction at temperatures above 845 °C as well as for the hydrogen evolution reaction are not consistent with a charge-transfer-controlled electrode reaction. Adsorption and chemical reaction between adsorbed species are considered to be dominant for the hydrogen oxidation reaction at temperatures above 845 °C and the hydrogen evolution reaction over the entire temperature range studied.
UR - http://www.scopus.com/inward/record.url?scp=0032687834&partnerID=8YFLogxK
U2 - 10.1149/1.1391816
DO - 10.1149/1.1391816
M3 - Article
AN - SCOPUS:0032687834
SN - 0013-4651
VL - 146
SP - 1620
EP - 1625
JO - Journal of the Electrochemical Society
JF - Journal of the Electrochemical Society
IS - 5
ER -