New Electro-Fenton Gas Diffusion Cathode based on Nitrogen-doped Graphene@Carbon Nanotube Composite Materials

Abstract

For the development of a highly active and energy-effective electro-Fenton process, a novel nitrogen-doped graphene@carbon nanotube composite material (N-G@CNT) is prepared, characterized, investigated for the oxygen reduction reaction (ORR), and employed for dimethyl phthalate (DMP) degradation in aqueous solution. It is found that N-G@CNT’s ORR activity towards H2O2 production is significantly improved in terms of increased current density and more positive onset potential. Moreover, −0.2V (vs. SCE) is the lowest cathodic potential, to our best knowledge, in which DMP degrades over N-G@CNT GDE (Gas Diffusion Electrode) more effectively than over: i) graphite GDE or ii) graphene GDE or iii) CNT GDE. The apparent rate constant of DMP degradation is found to be 0.0322min−1, about 14, 19, and 54 times higher than those measured on the above three types of GDEs, respectively. It is also found that, at the lower potential (−0.2V), the energy consumption (EC) for the half-life time degradation of DMP over the studied GDEs, is as follows (inJmg−1): N-G@CNT=2.56<graphite=10.61<graphene=12.23<CNT=38.35. The lower onset potential could be attributed to both the bridge between graphene and CNT and the nitrogen doping. The as-prepared N-G@CNT exhibits high activity and desirable stability, and represents a potential candidate material as electro-Fenton cathode for energy-effective wastewater treatment.