Hydrophobic PVDF Nanofibers-covered Cathode and Corn cob-based anode for Enhanced Energy Sewage Wastewater-driven Microbial Fuel Cells
Barakat, N., Gamal, S., Nassar, M., Fadali, O., Abdelraheem, O., Moustafa, H. (2023). Hydrophobic PVDF Nanofibers-covered Cathode and Corn cob-based anode for Enhanced Energy Sewage Wastewater-driven Microbial Fuel Cells. EKB Journal Management System, (), -. doi: 10.21608/jaet.2023.216411.1251
Nasser AM Barakat; Shimaa Gamal; Mamdouh Nassar; Olfat Fadali; Omina Abdelraheem; Hager Moustafa. "Hydrophobic PVDF Nanofibers-covered Cathode and Corn cob-based anode for Enhanced Energy Sewage Wastewater-driven Microbial Fuel Cells". EKB Journal Management System, , , 2023, -. doi: 10.21608/jaet.2023.216411.1251
Barakat, N., Gamal, S., Nassar, M., Fadali, O., Abdelraheem, O., Moustafa, H. (2023). 'Hydrophobic PVDF Nanofibers-covered Cathode and Corn cob-based anode for Enhanced Energy Sewage Wastewater-driven Microbial Fuel Cells', EKB Journal Management System, (), pp. -. doi: 10.21608/jaet.2023.216411.1251
Barakat, N., Gamal, S., Nassar, M., Fadali, O., Abdelraheem, O., Moustafa, H. Hydrophobic PVDF Nanofibers-covered Cathode and Corn cob-based anode for Enhanced Energy Sewage Wastewater-driven Microbial Fuel Cells. EKB Journal Management System, 2023; (): -. doi: 10.21608/jaet.2023.216411.1251

Hydrophobic PVDF Nanofibers-covered Cathode and Corn cob-based anode for Enhanced Energy Sewage Wastewater-driven Microbial Fuel Cells

Journal of Advanced Engineering Trends
Articles in Press, Accepted Manuscript, Available Online from 27 July 2023  XML
Document Type: Original Article
DOI: 10.21608/jaet.2023.216411.1251
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Authors
Nasser AM Barakat email 1; Shimaa Gamal2; Mamdouh Nassar1; Olfat Fadali3; Omina Abdelraheem4; Hager Moustafa1
1Minia University
2Chemical Engineering Department, Faculty of Engineering, Minia University
3Chemical Engineering Department, Faculty of Engineering. Minia University,
4Sciences Engineering Department, Faculty of Engineering, Beni-Suef University
Abstract
In this study, we present a novel approach to enhance power generation in MFCs by incorporating several innovative modifications. The MFC design eliminated the need for a membrane by depositing a hydrophobic PVDF nanofibers layer to facilitate oxygen penetration while preventing water passing. Additionally, a new anode material was developed by sintering corn cob under a nitrogen atmosphere, providing improved performance and cost-effectiveness. The MFC operated as an air-cathode system, eliminating the need for expensive electron acceptors. Furthermore, the MFC was driven by sewage wastewater, demonstrating the potential for waste-to-energy conversion. The power generation performance of the MFC was evaluated and compared to traditional carbon-based anode materials. The results showed a significant increase in power density with the corn cob anode, reaching 515 W/m2. In comparison, the power densities obtained with carbon felt, carbon cloth, and carbon paper anodes were 94, 95, and 140 W/m2, respectively. These findings highlight the superiority of the corn cob anode in terms of power generation efficiency. The demonstrated increase in power density with the corn cob anode highlights the potential for scaling up MFCs for practical applications, including wastewater treatment and remote power sources.
Keywords
Microbial Fuel Cell; Renewable Energy; Electrospinning; Corn cob anode; Power density
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