Catalytic dehydrogenation of propane has recently received considerable attention because of the increasing demand for propane. In this present work, the catalytic performances of layered nanowires of Mg 0.15V 2O 5.152.4H 2O with equal weight of either Al 2O 3 or SiO 2 were investigated in propane dehydrogenation and compared with the bulk commercial V 2O 5, at atmospheric pressure and temperature range of 500-600°C. Both dehydrogenation and cracking reactions products were obtained; which suggested sites of different relativities. The catalysts exhibited propylene, ethylene, ethane and methane as primary products. The highest propylene yield of 17% was obtained in the presence of Al 2O 3. The nanowire samples exhibited higher selectivity to propylene than bulk samples at similar level of propane conversions. For the nanowire samples, the conversion increased (1-3%) while selectivity to propylene decreased (96-87%). At low propane conversions (<1%), the primary products were propylene and ethylene. As the conversion increased, methane was also formed. But not observable amount of ethane was recorded. In the same partial pressure range (0.14-0.43atm), the bulk samples exhibited lower level of propane conversions (0.2-1.2%) and insignificant change in selectivity to propylene (71-73%). In this case, propylene, ethylene and methane are primary products. Although cracking is only observable at conversion higher than 1% on the nanosized samples, the bulk sample exhibited cracking products even at lower conversions. This implies that the nanowire sample exhibited better performance due to lower population of sites that lead to cracking reactions.
ASJC Scopus subject areas
- Environmental Chemistry
- Chemical Engineering(all)
- Industrial and Manufacturing Engineering