• Title/Summary/Keyword: microbial fuel cell (MFC)

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Current Research Trends in Microbial Fuel Cell Based on Polymer Electrolyte Membranes (고분자 전해질 분리막 기반 미생물 연료전지의 최근 연구동향)

  • Choi, Tae-Hwan;Kim, Hyo-Won;Park, Ho-Bum
    • Membrane Journal
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    • v.20 no.3
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    • pp.173-184
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    • 2010
  • Microbial fuel cell (MFC) is a promising renewable energy source that can generate electrical energy from organic wastes using microbe. This technology has been regarded as a future green alternative energy in that MFC makes use of organic-rich wastewater and also reduces waste sludges as well as produces electricity. To be practically realized, however, achieving higher power density than now is demanded, which may be possible by eliminating various negative factors to act as resistances in MFC operations. For instance, highly activated microbes, highly conductive electrode materials, and fast electron transfer between microbes and electrodes can lead to MFC with high power density. In particular, polymer electrolyte membranes are also a key component for improved MFC performance.

Effects of anode surface area and methylene blue dye treatment on the power density of microbial fuel cell with sponge and carbon nano tube electrode (음극 전극 표면적과 메틸렌블루 염색이 스펀지 탄소나노 튜브 전극 미생물 연료전지의 전력수율에 미치는 영향)

  • Lee, Chae-Young;Park, Su-Hee;Song, Young-Chae;Woo, Jung-Hui;Yoo, Kyu-Seon;Chung, Jae-Woo;Han, Sun-Kee
    • Journal of Korean Society of Water and Wastewater
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    • v.26 no.6
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    • pp.883-888
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    • 2012
  • Anode electrode is one of the most important factors in microbial fuel cell (MFC). This study was conducted to investigate the effects of mediator as methylene blue (MB) and electrode surface area on the power density of MFC with sponge and carbon nano tube (CNT) electrode (SC). The SC electrode with MB (MC) showed the maximum power density increased from 74.0 $mW/m^2$ to 143.1 $mW/m^2$. The grid shaped sponge and CNT (GSC) electrode showed the maximum power density of 209.2 $mW/m^2$ due to the increase of surface area from 88.0 to 152.0 $cm^2$. The GSC electrode with MB (GMC) revealed the maximum power density of 384.9 $mW/m^2$ which was 5.2 times higher than that obtained from the MFC with SC. Therefore MB and increase of surface area led to enhance the performance of microbial fuel cell such as power density.

Power Density Enhancement of Anion-Exchange Membrane-Installed Microbial Fuel Cell Under Bicarbonate-Buffered Cathode Condition

  • Piao, Jingmei;An, Junyeong;Ha, Phuc Thi;Kim, Taeyoung;Jang, Jae Kyung;Moon3, Hyunsoo;Chang, In Seop
    • Journal of Microbiology and Biotechnology
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    • v.23 no.1
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    • pp.36-39
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    • 2013
  • We introduce a high-performance microbial fuel cell (MFC) that was operated using a 0.1M bicarbonate buffer as the cathodic electrolyte. The MFC had a 136.42 $mW/m^2$ maximum power density under continuous feeding of 5 mM acetate as fuel. Results of the electrode potential measurements showed that the cathode potential of the bicarbonate-buffered condition was higher than the phosphate-buffered condition, although the phosphate condition had less interfacial resistance between the membrane and electrolyte. Therefore, we posit here that the increased power of the bicarbonate-buffered MFC may be caused by the higher cathode potential rather than by the interfacial membrane-electrolyte resistance.

Improved Performance of a Microbial Fuel Cell with Polypyrrole/Carbon Black Composite Coated Carbon Paper Anodes

  • Yuan, Yong;Kim, Sung-Hyun
    • Bulletin of the Korean Chemical Society
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    • v.29 no.7
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    • pp.1344-1348
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    • 2008
  • A microbial fuel cell (MFC) has been regarded as noble clean energy technology that can directly convert biomass to electricity. However, its low power density is a main limitation to be used as a new energy source. To overcome this limitation, we focused on the anode improvement in a mediator-type MFC using P. vulgaris as a biocatalyst. Fuel cell performance increased when the anode was coated with carbon black or polypyrrole. The best performance was observed when polypyrrole/carbon black (Ppy/CB) composite material was coated on a carbon paper electrode. Our obtained value of 452 mW $m^{-2}$ is the highest value among the reported ones for the similar system. The effects of amount of Ppy/CB, mediator concentration, and amount of P. vulgaris have also been examined.

Evaluation of power density in microbial fuel cells using expanded graphite/carbon nanotube (CNT) composite cathode and CNT anode (팽창흑연·소나노튜브 복합 음극과 탄소나노튜브 양극으로 이루어진 미생물 연료전지의 전력수율 평가)

  • Han, Sun-Kee;Lee, Chae-Young
    • Journal of Korean Society of Water and Wastewater
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    • v.27 no.4
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    • pp.503-509
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    • 2013
  • Electrochemical redox capacity of a microbial fuel cell (MFC) electrode is an important factor in the power density. This study was conducted to investigate the redox capacity of surface modified anode and cathode electrodes by measuring their conductivities. An anode electrode was modified with nitric acid and a cathode electrode was modified with heat treatment. The anode electrode modified with 20 % of the nitric acid concentration showed the highest conductivity of $6.2{\mu}S/cm/g$ and the maximum power density of $306.0mW/m^2$ when used in a MFC. The cathode electrode modified at $472^{\circ}C$ for 18 min showed the highest conductivity of $5.2{\mu}S/cm/g$ and the maximum power density of $276.20mW/m^2$ when used in a MFC. On the other hand, an MFC using both the electrodes showed the highest maximum power density of $408.2mW/m^2$. Meanwhile, a control MFC without modified electrodes generated very small voltage (0.014 mV), so the power density could not be measured.

Review on Proton Exchange Membranes for Microbial Fuel Cell Application (미생물 연료 전지 적용을 위한 양성자 교환막에 대한 검토)

  • Kim, Ji Min;Patel, Rajkumar
    • Membrane Journal
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    • v.30 no.4
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    • pp.213-227
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    • 2020
  • As unrenewable energy resources have depleted over the years, the demand for renewable energy has increased promoting research for more effective methods to produce renewable energy. The field of fuel cell development, specifically microbial fuel cells (MFCs), has developed because of the dual performance potential of the technology. MFCs convert power by facilitating electrode-reducing organisms such as bacteria (microbes) as a catalyst to produce electrical energy. MFCs use domestic and industrial wastewater as fuel to initiate the process, purifying the wastewater as a result. Proton exchange membranes (PEM) play a crucial role in MFCs as a separator between the anodes and cathodes chambers allowing only protons to effectively pass through. Nafion is the commercially used PEM for MFCs, but there are many setbacks: such as cost, production time, and less effective proton conductivity properties. In this review there will be largely two parts. Firstly, several newly developed PEM are discussed as possible replacements of Nafion. Secondly, MFC based on PEM, blended PEM and composite PEM are summarized.

Characteristics of Electricity Production from Volatile Fatty Acids Using a Microbial Fuel Cell (미생물연료전자를 이용한 유기산으로부터 전기생산 특성)

  • Noh, Jung-bin;Hwang, Yong-woo;Bae, Jae-ho;Moon, Jin-young
    • Journal of Korean Society of Water and Wastewater
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    • v.20 no.2
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    • pp.225-234
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    • 2006
  • Characteristics of electricity production from major fermentation products (acetate, propionate and butyrate) were evaluated in a microbial fuel cell (MFC). For each substrate, batch and continuous experiments were performed. The batch test result indicated that coulombic efficiency depended on the resistance connected in MFC circuit. With acetate, coulombic efficiency were 87% at $20{\Omega}$, but decreaced to 45% at$220{\Omega}$. In continuous tests, maximum power densities obtained was 220 Q with acetate. The maximum power densities of butyrate, acetate and propionate were 6.8, 6.1, and $5.2mW/m^2$, respectively. Propionate and butyrate were converted into acetate producing high currents. $H_2$ produced during butyrate and propionate probably used to produce electricity. In conclusion, butyrate conversion into acetate was faster than that of propionate with higher electricity production. If the production of propionate is inhibited during fermentation, anaerobically fermented liguor may be effectively applied for MFC.

Comparison of Electricity Generation and Microbial Community Structure in MFCs Fed with Different Substrates (미생물연료전지에서 공급기질에 따른 전기발생량 및 미생물 군집구조 비교)

  • Yu, Jaecheul;Cho, Haein;Cho, Sunja;Lee, Taeho
    • Journal of Korean Society on Water Environment
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    • v.26 no.4
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    • pp.608-613
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    • 2010
  • Electricity generation of microbial fuel cells (MFC) is greatly affected by the kind of feed substrates because substrates would change microbial community of electrochemically active bacteria (EAB) able to transfer electrons to electrode. The effect of different substrates on electricity generation and microbial community of MFC was investigated. Two-chamber MFCs fed with acetate (A-MFC), butyrate (B-MFC), propionate (P-MFC), glucose (G-MFC) and a mixture (M-MFC) of the 4 substrates (acetate : butyrate : propionate : glucose = 1 : 1 : 1 : 1 as $COD_{Cr}$ base) were operated under continuous mode. The maximum power density was found from the M-MFC ($190W/m^3$) which showed the lowest internal resistance ($89{\Omega}$). The maximum power densities of the pure substrates feed MFCs were in order of A-MFC ($25W/m^3$), P-MFC ($21W/m^3$), B-MFC ($20W/m^3$) and G-MFC ($9W/m^3$). In DGGE analysis, the microbial community structure in suspension was quite different from each others depending on feed substrates, while the community structure in the biofilm was relatively similar regardless of the substrates. This result suggests that the feed substrates would affect the microbial community of suspended growth bacteria than attached growth bacteria resulting in difference of electricity generation in MFCs.

Basic Study for Harvesting Unused Energy based on Plant-Microbial Electrochemical Technology (식물-미생물전기화학 기반의 미활용 에너지 회수 기초 연구)

  • Yu, Jaecheul;Shin, Choon Hwan
    • Journal of Environmental Science International
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    • v.28 no.2
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    • pp.219-224
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    • 2019
  • In this study, we evaluated the energy production from plant-microbial fuel cells using representative indoor plants, such as Scindapsus aureus and Clatha minor. The maximum power density of microbial fuel cell (MFC) using S. aureus ($3.36mW/m^2$) was about 2 times higher than that of the MFC using C. minor ($1.43mW/m^2$). It was confirmed that energy recovery is possible using plant-MFCs without fuel. However, further research is needed to improve the performance of plant-MFCs. Nevertheless, plant-MFCs have proved their potential as a novel energy source to overcome the limitations of the conventional renewable energy sources such as wind power and solar cells, and could be employed to a power source for the sensor in charge of the fourth industrial revolution.

Enhanced Current Production by Electroactive Biofilm of Sulfate-Reducing Bacteria in the Microbial Fuel Cell

  • Eaktasang, Numfon;Kang, Christina S.;Ryu, Song Jung;Suma, Yanasinee;Kim, Han S.
    • Environmental Engineering Research
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    • v.18 no.4
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    • pp.277-281
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    • 2013
  • A dual-chamber microbial fuel cell (MFC) inoculated with Desulfovibrio desulfuricans and supplemented with lactate as an organic fuel was employed in this study. Biofilm formed on the anodic electrode was examined by scanning electron microscopy, revealing that the amount of biofilm was increased with repeated cycles of MFC operation. The maximum current production was notably increased from the first cycle ($1,310.0{\pm}22.3mA/m^2$) to the final cycle ($1,539.4{\pm}25.8mA/m^2$) of MFC run. Coulombic efficiency was also increased from $89.4%{\pm}0.2%$ to $98.9%{\pm}0.5%$. We suggest that the current production efficiency was related to the biomass of biofilm formed on the electrode, which was also increased as the MFC run was repeated. It was also found that D. desulfuricans, which colonized on the electrode, produced filaments or nano-pili. Nano-pili were effective for the attachment of cells on the electrode. In addition, the nano-pili provided a cell-to-cell link and stimulated the development of thicker electroactive biofilm, and therefore, they facilitated electron transfer to the anode. Conclusively, the biofilm of D. desulfuricans enhanced the current production in the MFC as a result of effective attachment of cells and electron transfer from the cell network to the electrode.