화학공학소재연구정보센터
Materials Chemistry and Physics, Vol.101, No.1, 182-190, 2007
Effects of thermal treatment and doping with cobalt and manganese oxides on surface and catalytic properties of ferric oxide
The effects of doping and thermal treatment on surface and catalytic properties of pure ferric oxide solid were studied by means of thermal analyses (TG-DTG-DTA), X-ray powder diffractometry, BET analysis of nitrogen isotherms and hydrogen peroxide decomposition reaction at 20-50 degrees C. These techniques used for investigating the thermal behavior of pure and variously doped samples, crystalline bulk structure, specific surface areas and testing catalytic properties of pure and variously doped samples, respectively. A series of Co3O4-Fe2O3 and Mn2O3-Fe2O3 systems were prepared from cobalt nitrate, basic ferrous carbonate and manganese nitrate salts by impregnation method. Both of Co3O4 and Mn2O3 used as dopants (0.25-4.00 mol%) for pure Fe2O3. The pure and doped solids were conducted at 350, 550, 750 and 1000 degrees C. The results obtained revealed that the various solids heated at low temperature led to formation of free oxides. The doped solids calcined at high temperature resulted in formation of ferrite compounds (CoFe2O4 or MnFe2O4). The specific surface area of pure Fe2O3 progressively affected by amount of dopants and calcination temperature. It significantly increased with increasing amount of dopants for solids treated at 350 and 550 degrees C then it dramatically decreased with increasing the calcination temperature up to 750 degrees C. The increase was, however, more pronounced in case of Mn2O3-doping. The catalytic activity of pure Fe2O3 significantly increased with increasing the amount of cobalt or manganese oxides dopants. The observed increase in activity is attributed to increasing the concentration of catalytically active constituents and/or formation of new active sites. The measurement of activation energy of the catalytic reaction for pure and variously doped solids revealed that the doping process did not modify the energetic nature of the active sites involved in the catalyzed reaction. Furthermore, the catalytic activities of doped solids increased by increasing calcination temperature from 350 to 550 degrees C then it significantly decreased with increasing treatment temperature up to 750 degrees C. The progressive decrease in the activity is due to formation of inactive ferrite compounds and/or sintering processes. (c) 2006 Published by Elsevier B.V.