Chemical Research in Chinese Universities ›› 2002, Vol. 18 ›› Issue (2): 139-145.

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Effects of Thermal Activation on the El ectrocatalysis of the Ru(O001) Surface

Wenfeng Lin, Jiamei Jin, Paul A. Christensen   

  1. Department of Chemistry, Bedson Building, The University, Newcastle upon Tyne, NE1 7RU, UK
  • Received:2001-12-06 Online:2002-04-24 Published:2011-08-04
  • Supported by:

    Support by the UK EPSRC.

Abstract: Variable-temperature in-situ FTIR spectroscopy has been used as the primary tool to investigate the effects of temperature (10 to 50 C ) on formaldehyde dissociative adsorption and electro-oxidation on the Ru (0001) electrode in perchloric acid solution, and the results were interpreted in terms of the surface chemistry of the Ru (0001) electrode and compared to those obtained during our previous studies on the adsorption of CO under the same conditions. It was found that formaldehyde did undergo dissociative adsorption, even at -200 mV vs. Ag/AgCl, to form linear (COL) and 3-fold-hollow(COH) binding CO adsorbates. In contrast to the adsorption of .CO, it was found that increasing the temperature to 50℃ markedly increased the amount of CO adsorbates formed on the Ru(0001) surface from the adsorption of formaldehyde. On increasing the potential, the electrooxidation of the CO adsorbates to CO2 took place via reaction with the active (1×1)-O oxide. A significant increase in the surface reactivity was observed on the RuO2(100) phase formed at higher potentials. Formic acid was detected as a partial oxidation product during formaldehyde electro-oxidation. The data obtained at 50℃are markedly different from those collected at 10 and 25℃ in terms of the amount of both CO2 and formic acid formed and the adsorbed COL and COH species observed. These results were rationalized by the thermal effects on both the loosening of the CO adlayer and the activation of surface oxide on increasing the temperature.

Key words: Ruthenium single crystal electrode, In-situ FTIR, Thermal activation, Electrocatalysis, Surface chemistry