Fe, N-doped carbonaceous catalyst activating periodate for micropollutant removal: Significant role of electron transfer

In this study, the performance of periodate (PI) on sulfadiazine (SDZ) degradation was evaluated using coagulation solid waste fabricated catalyst (CWBC), obtained by simple pyrolysis. SDZ effectively underwent 98.94% remove within 90 min in the CWBC/PI system. Electron transfer was the predominant mechanism due to the development of an electronic cycle among SDZ, CWBC and PI, where the O-2(center dot-), PFRs, and the reactive iodine species had minor roles. Density functional theory calculations identified that Fe and N could change the electron configuration and break the chemical inertness of carbonaceous material. As a result, electrons on the carbon matrix of CWBC are inclined to travel through the formed Fe-O covalent bond to PI. Further analysis demonstrated that SO42-, humic acid (HA), as well as anoxic conditions greatly facilitated SDZ degradation. This study provides a facile protocol for converting coagulation waste to an efficient catalyst and provides fundamental insights into the degradation mechanisms of micropollutants by activating PI.

Automated summary

This study evaluates the efficiency of periodate in degrading sulfadiazine and identifies electron transfer as the predominant mechanism. The formation of an electronic cycle among SDZ, CWBC, and PI leads to a high removal rate of 98.94%. Additionally, the impact of Fe and N on the electron configuration of carbonaceous materials is investigated.