Dramatic enhancement of organics degradation and electricity generation via strengthening superoxide radical by using a novel 3D AQS/PPy-GF cathode

A dramatic enhancement of organics degradation and electricity generation has been achieved in a wastewater fuel cell (WFC) system via strengthening superoxide radical with radical chain reaction by using a novel 3D anthraquinone/polypyrrole modified graphite felt (AQS/PPy-GF) cathode. The AQS/PPy-GF was synthesized by one-pot electrochemical polymerization method and used to in-situ generate superoxide radical by reducing oxygen under self-imposed electric field. Results showed that methyl orange (MO) were effectively degraded in AQS/PPy-GF/Fe2+ system with a high apparent rate constant (0.0677 min(-1)), which was 3.9 times that (0.0174 min(-1)) in the Pt/Fe2+ system and even 9.4 times that (0.0072 min(-1)) in the traditional WFC system (without Fe2+). Meanwhile, it showed a superior performance for electricity generation and the maximum power density output (1.130 mW cm(-2)) was nearly 33 times and 5.0 times higher, respectively, when compared with the Pt/Fe2+ system and traditional WFC. This dramatic advance was attributed to 3D AQS/PPy-GF cathode which produces more center dot O-2(-) via one electron reduction process. The presence of center dot O-2(-) cannot only directly contribute to MO degradation, but also promotes the final complete mineralization by turning itself to center dot O-2(-). Additionally, center dot O-2(-) accelerates the Fe2+/Fe3+ couple cycling, thus avoiding continuous addition of any external ferrous ions. Inhibition and probe studies were conducted to ascertain the role of several radicals (center dot OH and center dot O-2(-)) on the MO degradation. Superoxide radicals were considered as the primary reactive oxidants, and the degradation mechanism of MO was proposed. The proposed WFC system provides a more economical and efficient way for energy recovery and wastewater treatment. (C) 2017 Elsevier Ltd. All rights reserved.