The mechanism of palladium-catalyzed decomposition of ethanol - a comparison of chemical kinetic and surface science studies

Abstract

The decomposition reactions of ethanol and ethanal over Pd/Al₂O₃ have been studied in pulse reaction mode at 200°C in flowing helium and with added H₂, CO, and H₂O. Ethanal decomposes to CH₄ and CO with progressive coking that can be suppressed by H₂. The response times, as monitored by MS peaks at m/e = 16 for methane and m/e = 28 for CO, are very similar. Ethanol decomposes to CH₄/CO/H₂, the corresponding traces being either broad and unsymmetrical or resolved into two peaks. In H₂/He, the slower set of responses is suppressed, and those from CH₄ and CO appear sharp and similar in shape to those observed from ethanal. Two independent mechanistic paths for the catalytic reaction of ethanol are proposed, based on a comparison with published TPR data from reactions on Pd(111) and Pd(110) single-crystal surfaces. A comparison between the classical kinetic (LHHW) and surface science approaches is made.