Innovative multi‐processed N‐doped carbon and Fe
            <sub>3</sub>
            O
            <sub>4</sub>
            cathode for enhanced bioelectro‐Fenton microbial fuel cell performance

Wu, Jung-Chen; Yan, Wei‐Mon; Chiang, Wei‐Hung; Sangeetha, T.; Wang, Chen‐Hao; Wang, Chin‐Tsan

doi:10.1002/er.4746

Cited by 7 publications

(6 citation statements)

References 58 publications

(87 reference statements)

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“…As concluded from Raman and XPS results, there is abundant graphitic and N, S co-doped carbon, which owns high electrical conductivity and can improve the charge transfer efficiency of electrocatalysts. 45,46 The contents of highly-conductive carbon species in the prepared samples follow a similar trend to that of charge transfer efficiency. It indicates that the highest degree of graphitization and content of N, S co-doped carbon in Ni60Fe40 S/NSC contributes much to its superior charge transfer efficiency during OER.…”

Section: Resultssupporting

confidence: 57%

“…The R ct values increase with the Ni/Fe feeding molar ratio further decreasing from 60/40 to 40/60 (Figure S10B), indicating the decrease of charge transfer efficiency. As concluded from Raman and XPS results, there is abundant graphitic and N, S co‐doped carbon, which owns high electrical conductivity and can improve the charge transfer efficiency of electrocatalysts 45,46 . The contents of highly‐conductive carbon species in the prepared samples follow a similar trend to that of charge transfer efficiency.…”

Section: Resultssupporting

confidence: 53%

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NiSFeS/N, S co‐doped carbon hybrid: Synergistic effect between NiS and FeS facilitating electrochemical oxygen evolution reaction

Zhao

Yin

et al. 2020

Int J Energy Res

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Summary A series of NiSFeS/N, S co‐doped carbon (NixFeyS/NSC) for electrochemical oxygen evolution reaction (OER) were synthesized by a co‐precipitation method and followed by pyrolysis in N2 atmosphere. NiSFeS hybrid was uniformly integrated with N, S co‐doped carbon in NixFeyS/NSC. NixFeyS/NSC showed high OER catalytic activity, and the optimized Ni60Fe40S/NSC afforded an OER overpotential of ~239 mV to deliver a current density of 10 mA cm−2 and showed a corresponding Tafel slope of ~30.9 mV dec−1 in 1 M KOH. Such OER catalytic activity was not only higher than that of IrO2, but also comparable with that of the most recently reported NiFe‐based sulfides for OER. Further study indicated that hybridizing NiS with FeS resulted in a synergistic effect for OER. The hybridization increased total amount of sulfides as active species, therefore enhancing the OER catalytic activity. In addition, the hybridization benefited the formation of petal‐like morphologies that contributing much to higher electrochemically active surface area (ECSA), and also boosted the content of graphitic and N, S co‐doped carbon that improving charge transfer efficiency.

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Section: Resultssupporting

confidence: 57%

Section: Resultssupporting

confidence: 53%

NiSFeS/N, S co‐doped carbon hybrid: Synergistic effect between NiS and FeS facilitating electrochemical oxygen evolution reaction

Zhao

Yin

et al. 2020

Int J Energy Res

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“…Platinum has historically been the go-to catalyst for the ORR in MFCs due to its exceptional efficiency. While platinum (Pt)-based materials remain the benchmark for ORR catalysis, their drawbacks-such as limited availability, elevated costs, poor durability, and susceptibility to poisoninginduced inactivation-have prompted a fervent exploration of more sustainable alternatives (Wu et al, 2019;Xu et al, 2019;Zhang et al, 2021b). In this context, researchers are increasingly focusing on the development of advanced, cost-effective materials to supplant Pt-based counterparts.…”

Section: Introductionmentioning

confidence: 99%

Synergistic advancements in sewage-driven microbial fuel cells: novel carbon nanotube cathodes and biomass-derived anodes for efficient renewable energy generation and wastewater treatment

Barakat,

Gamal,

Kim

et al. 2023

Front. Chem.

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Microbial fuel cells (MFCs) offer a dual solution of generating electrical energy from organic pollutants-laden wastewater while treating it. This study focuses on enhancing MFC performance through innovative electrode design. Three-dimensional (3D) anodes, created from corncobs and mango seeds via controlled graphitization, achieved remarkable power densities. The newly developed electrode configurations were evaluated within sewage wastewater-driven MFCs without the introduction of external microorganisms or prior treatment of the wastewater. At 1,000°C and 1,100°C graphitization temperatures, corncob and mango seed anodes produced 1,963 and 2,171 mW/m2, respectively, nearly 20 times higher than conventional carbon cloth and paper anodes. An advanced cathode composed of an activated carbon-carbon nanotube composite was introduced, rivaling expensive platinum-based cathodes. By optimizing the thermal treatment temperature and carbon nanotube content of the proposed cathode, comparable or superior performance to standard Pt/C commercial cathodes was achieved. Specifically, MFCs assembled with corncob anode with the proposed and standard Pt/C cathodes reached power densities of 1,963.1 and 2,178.6 mW/m2, respectively. Similarly, when utilizing graphitized mango seeds at 1,100°C, power densities of 2,171 and 2,151 mW/m2 were achieved for the new and standard cathodes, respectively. Furthermore, in continuous operation with a flow rate of 2 L/h, impressive chemical oxygen demand (COD) removal rates of 77% and 85% were achieved with corncob and mango seed anodes, respectively. This work highlights the significance of electrode design for enhancing MFC efficiency in electricity generation and wastewater treatment.

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“…Platinum (Pt)-based materials are still the most efficient ORR catalysts at present, despite their shortcomings, such as low reserves, high cost, poor durability, and inactivation caused by poisoning. Given these disadvantages of the noble metal catalysts, numerous scientists are exploring advanced, low-cost materials to replace Pt-based materials [ 15 , 16 , 17 ]. In particular, carbon-based electrocatalysts containing Fe and N elements (Fe-N/C) have been widely used as the most promising alternatives to noble metal Pt, due to the similar catalytic activity and abundant precursor species [ 18 , 19 ].…”

Section: Introductionmentioning

confidence: 99%

Preparation and Application of Fe-N Co-Doped GNR@CNT Cathode Oxygen Reduction Reaction Catalyst in Microbial Fuel Cells

Zhang

Song

2021

Nanomaterials

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Through one-step pyrolysis, non-noble-metal oxygen reduction reaction (ORR) electrocatalysts were constructed from ferric trichloride, melamine, and graphene nanoribbon@carbon nanotube (GNR@CNT), in which a portion of the multiwall carbon nanotube is unwrapped/unzipped radially, and thus graphene nanoribbon is exposed. In this study, Fe-N/GNR@CNT materials were used as an air-cathode electrocatalyst in microbial fuel cells (MFCs) for the first time. The Fe-N/C shows similar power generation ability to commercial Pt/C, and its electron transfer number is 3.57, indicating that the ORR process primarily occurs with 4-electron. Fe species, pyridinic-N, graphitic-N, and oxygen-containing groups existing in GNR@CNT frameworks are likely to endow the electrocatalysts with good ORR performance, suggesting that a GNR@CNT-based carbon supporter would be a good candidate for the non-precious metal catalyst to replace Pt-based precious metal.

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Innovative multi‐processed N‐doped carbon and Fe ₃ O ₄ cathode for enhanced bioelectro‐Fenton microbial fuel cell performance

Cited by 7 publications

References 58 publications

NiSFeS/N, S co‐doped carbon hybrid: Synergistic effect between NiS and FeS facilitating electrochemical oxygen evolution reaction

NiSFeS/N, S co‐doped carbon hybrid: Synergistic effect between NiS and FeS facilitating electrochemical oxygen evolution reaction

Synergistic advancements in sewage-driven microbial fuel cells: novel carbon nanotube cathodes and biomass-derived anodes for efficient renewable energy generation and wastewater treatment

Preparation and Application of Fe-N Co-Doped GNR@CNT Cathode Oxygen Reduction Reaction Catalyst in Microbial Fuel Cells

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Innovative multi‐processed N‐doped carbon and Fe 3 O 4 cathode for enhanced bioelectro‐Fenton microbial fuel cell performance

Cited by 7 publications

References 58 publications

NiSFeS/N, S co‐doped carbon hybrid: Synergistic effect between NiS and FeS facilitating electrochemical oxygen evolution reaction

NiSFeS/N, S co‐doped carbon hybrid: Synergistic effect between NiS and FeS facilitating electrochemical oxygen evolution reaction

Synergistic advancements in sewage-driven microbial fuel cells: novel carbon nanotube cathodes and biomass-derived anodes for efficient renewable energy generation and wastewater treatment

Preparation and Application of Fe-N Co-Doped GNR@CNT Cathode Oxygen Reduction Reaction Catalyst in Microbial Fuel Cells

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Innovative multi‐processed N‐doped carbon and Fe ₃ O ₄ cathode for enhanced bioelectro‐Fenton microbial fuel cell performance