Kinetic Approach to Investigate the Mechanistic Pathways of Oxygen Reduction Reaction on Fe-Containing N-Doped Carbon Catalysts

The mechanism of the oxygen reduction reaction (ORR) on polyimide-based N-doped carbon catalysts with and without Fe (i.e., Fe-N-C and N-C) in acidic media was studied, using a rotating ring-disk electrode voltammetry, based on the estimation of the rate constants of the ORB, i.e., k(1), k(2), and k(3) corresponding to the 4-electron direct reduction of O-2 to H2O, the 2-electron reduction of O-2 to H2O2, and the 2-electron reduction of H2O2 to H2O, respectively as functions of the loading density of Fe-N-C or N-C and the electrode potential, in which two different kinetic models for the ORR, i.e., Damjanovic and Wroblowa models were used to estimate the values of the k(1), k(2), and k(3). The H2O2 disproportionation reaction rate constants (k(4)) of the Fe-N-C and N-C catalysts were also estimated. For both catalysts, the ORR follows, as a whole, a 4-electron pathway (k(1) >> k(2)) when the loading density is high (>ca. 200 mu g/cm(2)), whereas at the lower loading density the 2-electron reduction of O-2 becomes more dominant (k(1) < k(2)). The value of k(4) was found to be negligible compared with that of k(1), k(2), and k(3). In addition, the individual rate constants estimated by extrapolating rate constant vs loading density plots to the zero loading density demonstrate that in the case of the Fe-N-C catalyst, 2-electron and 4-electron reduction sites coexist with a higher population of the former, whereas in the case of the N-C catalyst, only 2-electron active sites exist. The kinetic analysis strongly suggests that the Fe in the Fe-N-C catalyst plays a crucial role in making the 4-electron active sites as well as it may catalyze the H2O2 reduction to H2O, resulting in the enhanced ORR performance.