Results on the oxidative conversion of propane on three types of catalysts on which different mechanisms of propane activation prevail are discussed, whereby the reaction conditions and final product distribution are affected. In the case of the redox-mechanism on V 2O 5-based catalysts the degree of catalyst reduction which is affected by the propane-to-oxygen ratio determines the catalyst activity and selectivity. On rare-earth oxide-based catalysts, activation of propane by adsorbed oxygen takes place. As derived from transient experiments under vacuum conditions, adsorbed oxygen species convert propane into C 3H 6, C 2H 4, CH 4, and CO x . Continuous flow experiments on Na–P/Sm 2O 3 (Na:P:Sm=2:1:700) and Ln 2O 3/SrO (Ln=Sm, La, Nd; Ln:Sr=5:1) catalysts at 1 bar showed that due to high catalyst activity the ignition of the reaction mixture takes place at 420–450°C. The heat produced by the oxidative conversion of propane was sufficient to sustain the reactions after ignition with the preheat of the feed gas under conditions chosen. Higher selectivity to C 2H 4 (ca. 30%) compared to C 3H 6 (ca. 20%) was observed in the whole range of the reaction conditions indicating that C–C splitting prevails when adsorbed oxygen participates in the reaction. Finally, propane activation via redox-mechanism and adsorbed oxygen is ruled out for B 2O 3/Al 2O 3 catalysts. The involvement of Lewis acid sites in the generation of propyl radicals is assumed; olefins and C 1–C 3 oxygenates are formed with high selectivities even in excess of oxygen most probably via secondary reactions of propyl radicals and oxygen in the gas phase.