Abstract
The use of a photocatalytic fuel cell (PFC) in wastewater treatment is an intensively researched topic because the device integrates organic pollutant degradation and chemical energy recovery. Herein, we proposed a strategy to enhance PFC performance by increasing the concentrations of hydroxyl radical (HO) and superoxide radical (O2−) produced from H2O2 generated in situ using an activated graphite felt (GF) cathode. This cathode was prepared by H2SO4 treatment to introduce oxygen-containing functional groups on its surface that would serve as surface-active sites and facilitate the two-electron pathway of H2O2 production. Remarkably, the peak current density of the activated GF cathode (−1.25 mA/cm2) was more than thrice that of the original GF cathode (−0.40 mA/cm2), and its Faradaic efficiency significantly improved from 20.01% to 74.09%. The PFC equipped with the activated GF cathode harvested 2.69 times the maximum power density (JVmax) and 5.15 times the degradation rate of the traditional Pt black-PFC system. This was because the O2− and HO concentrations, respectively, were 2.87 (23.98 × 10−5 M) and 2.48 times (13.00 × 10−4 M) as high as those in the Pt black-PFC system. These results were attributed to the high concentration of H2O2 generated in situ at the activated GF cathode, which was 25.13 times (0.402 mM) as high as that generated at the Pt black cathode. Thus, the proposed PFC system demonstrates the feasibility of improving organic pollutant degradation and energy recovery by enhancing H2O2 production.
Published Version
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