FeS2 Nanoparticles Decorated Graphene as Microbial‐Fuel‐Cell Anode Achieving High Power Density

Microbial fuel cells (MFCs) have received great attention worldwide due to their potential in recovering electrical energy from waste and inexhaustible biomass. Unfortunately, the difficulty of achieving the high power, especially in real samples, remains a bottleneck for their practical application...

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Published in:Advanced materials (Weinheim) 2018-05, Vol.30 (22), p.e1800618-n/a
Main Authors: Wang, Ruiwen, Yan, Mei, Li, Huidong, Zhang, Lu, Peng, Benqi, Sun, Jinzhi, Liu, Da, Liu, Shaoqin
Format: Article
Language:English
Subjects:
Biochemical fuel cells
bioelectricity
Biomass energy production
Cell anodes
Chemical oxygen demand
Decoration
Density
Electron transfer
FeS2 nanoparticles
Graphene
Hydrothermal reactions
Materials science
microbial fuel cells
Microorganisms
Nanoparticles
Power efficiency
Pyrite
Waste to energy
Wastewater
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container_title Advanced materials (Weinheim)
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creator Wang, Ruiwen
Yan, Mei
Li, Huidong
Zhang, Lu
Peng, Benqi
Sun, Jinzhi
Liu, Da
Liu, Shaoqin
description Microbial fuel cells (MFCs) have received great attention worldwide due to their potential in recovering electrical energy from waste and inexhaustible biomass. Unfortunately, the difficulty of achieving the high power, especially in real samples, remains a bottleneck for their practical applications. Herein, FeS2 nanoparticles decorated graphene is fabricated via a simple hydrothermal reaction. The FeS2 nanoparticles decorated graphene anode not only benefits bacterial adhesion and enrichment of electrochemically active Geobacter species on the electrode surface but also promotes efficient extracellular electron transfer, thus giving rise to a fast start‐up time of 2 d, an unprecedented power density of 3220 mW m−2 and a remarkable current density of 3.06 A m−2 in the acetate‐feeding and mixed bacteria‐based MFCs. Most importantly, the FeS2 nanoparticles decorated graphene anode successfully achieves a power density of 310 mW m−2 with simultaneous removal of 1319 ± 28 mg L−1 chemical oxygen demand in effluents from a beer factory wastewater. The characteristics of improved power generation and enhanced pollutant removal efficiency opens the door toward development of high‐performance MFCs via rational anode design for practical application. An FeS2 nanoparticles coated graphene (FeS2/rGO) anode not only benefits bacterial adhesion and Geobacter species enrichment, but also enhances the bacteria–electrode interaction and effectively promotes extracellular electron transfer from electroactive bacteria to the electrode, leading to a fast start‐up period and higher power density. The FeS2/rGO anode achieves a power density of 310 mW m‐2 with simultaneous removal of organic waste.
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The characteristics of improved power generation and enhanced pollutant removal efficiency opens the door toward development of high‐performance MFCs via rational anode design for practical application. An FeS2 nanoparticles coated graphene (FeS2/rGO) anode not only benefits bacterial adhesion and Geobacter species enrichment, but also enhances the bacteria–electrode interaction and effectively promotes extracellular electron transfer from electroactive bacteria to the electrode, leading to a fast start‐up period and higher power density. 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source Wiley-Blackwell Read & Publish Collection
subjects Biochemical fuel cells
bioelectricity
Biomass energy production
Cell anodes
Chemical oxygen demand
Decoration
Density
Electron transfer
FeS2 nanoparticles
Graphene
Hydrothermal reactions
Materials science
microbial fuel cells
Microorganisms
Nanoparticles
Power efficiency
Pyrite
Waste to energy
Wastewater
title FeS2 Nanoparticles Decorated Graphene as Microbial‐Fuel‐Cell Anode Achieving High Power Density
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