Abstract
Benthic microbial fuel cells (BMFCs) are considered to be one of the eco-friendly bioelectrochemical cell approaches nowadays. The utilization of waste materials in BMFCs is to generate energy and concurrently bioremediate the toxic metals from synthetic wastewater, which is an ideal approach. The use of novel electrode material and natural organic waste material as substrates can minimize the present challenges of the BMFCs. The present study is focused on cellulosic derived graphene-polyaniline (GO-PANI) composite anode fabrication in order to improve the electron transfer rate. Several electrochemical and physicochemical techniques are used to characterize the performance of anodes in BMFCs. The maximum current density during polarization behavior was found to be 87.71 mA/m2 in the presence of the GO-PANI anode with sweet potato as an organic substrate in BMFCs, while the GO-PANI offered 15.13 mA/m2 current density under the close circuit conditions in the presence of 1000 Ω external resistance. The modified graphene anode showed four times higher performance than the unmodified anode. Similarly, the remediation efficiency of GO-PANI was 65.51% for Cd (II) and 60.33% for Pb (II), which is also higher than the unmodified graphene anode. Furthermore, multiple parameters (pH, temperature, organic substrate) were optimized to validate the efficiency of the fabricated anode in different environmental atmospheres via BMFCs. In order to ensure the practice of BMFCs at industrial level, some present challenges and future perspectives are also considered briefly.
Highlights
Human beings are seriously involved with two main problems: energy inadequacy and less availability of hygienic water due to the wide utilization of non-renewable energy sources and unproductive wastewater technologies
The benthic microbial fuel cells (BMFCs) consist of two chambers: the anode chamber is filled with natural organic waste with target pollutant water, while the cathode is filled with aerated tap water
The BMFCs anode chamber was filled with 500 mL synthetic wastewater and 100 g sweet potato waste material, while the cathode was filled with tap water and 0.1 M phosphate buffer
Summary
Human beings are seriously involved with two main problems: energy inadequacy and less availability of hygienic water due to the wide utilization of non-renewable energy sources and unproductive wastewater technologies. MFCs is an approach in which bacterial species serve as catalysts to oxidize the supplied organic substrate to generate the electrons and proton [3,4]. The supplied organic substrate in BMFCs acts as an inoculum source, proton-exchange membrane (PEM) and nutrient-rich anodic medium This feature makes it different from other MFCs reactors and types [8]. Efforts are needed to improve BMFCs’ performance, which can solve some issues such as electron transportation, bacteria growth promotion, and efficient organic substrate at a low cost. Zhao et al [21] reported the graphene ribbons/PANI based anode catalyst in MFCs. The obtained results showed 6-fold higher energy output than a bare electrode.
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