Separator Characteristics for Increasing Performance of Microbial Fuel Cells

Zhang, Xiaoyuan; Cheng, Shaoan; Wang, Xin; Huang, Xia; Logan, Bruce E.

doi:10.1021/es901631p

Cited by 300 publications

(140 citation statements)

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“…The hydrogen evolution reaction often limits the overall MEC performance and cathodes with a larger surface area have demonstrated an increase in hydrogen production and current density (Call et al, 2009). Also, both MFC and MEC tests have demonstrated that the maximum power output can be increased by reducing the distance between the electrodes (Ghangrekar and Shinde, 2007;Liu et al, 2005a;Zhang et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Optimizing the electrode size and arrangement in a microbial electrolysis cell

Gil-Carrera

Mehta

Escapa

et al. 2011

Bioresource Technology

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This study investigates the influence of anode and cathode size and arrangement on hydrogen production in a membrane-less flat-plate microbial electrolysis cell (MEC). Protein measurements were used to evaluate microbial density in the carbon felt anode. The protein concentration was observed to significantly decrease with the increase in distance from the anode-cathode interface. Cathode placement on both sides of the carbon felt anode was found to increase the current, but also led to increased losses of hydrogen to hydrogenotrophic activity leading to methane production. Overall, the best performance was obtained in the flat-plate MEC with a two-layer 10 mm thick carbon felt anode and a single gas-diffusion cathode sandwiched between the anode and the hydrogen collection compartments.Crown

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Section: Introductionmentioning

confidence: 99%

Optimizing the electrode size and arrangement in a microbial electrolysis cell

Gil-Carrera

Mehta

Escapa

et al. 2011

Bioresource Technology

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“…A thick aerobic biofilm on the cathodes may function as a diffusion barrier to H + transfer to the catalyst site (Zhang X. et al, 2009;Ahmed, 2011), and it can severely block OH − transport outside the electrode, resulting in an significant OH − accumulation in the cathode microenvironment and thus a lower cathode potential (Yuan et al, 2013); the aerobic bacteria may consume a portion of the available oxygen at the catalytic sites and thus reduce the oxygen reduction kinetics Yuan et al, 2013); the EPS of attached microorganisms may also cause catalyst poisoning. Up to now, only the mechanisms of blockage of OH − and oxygen transfer by the cathodic biofilms have been demonstrated Yuan et al, 2013), the mechanisms how the aerobic biofilm affects cathode performance still need to be investigated.…”

Section: Reducing the Cathode Deteriorationmentioning

confidence: 99%

“…Up to now, only the mechanisms of blockage of OH − and oxygen transfer by the cathodic biofilms have been demonstrated Yuan et al, 2013), the mechanisms how the aerobic biofilm affects cathode performance still need to be investigated. As a result of biofilm growth, an increased internal resistance coupled with a decreased electricity (power) generation of MFCs was obtained in many studies (Cheng et al, 2006;Yang et al, 2009;Zhang X. et al, 2009;Zhang F. et al, 2011a). Therefore, it is important to develop effective methods to minimize the cathode bacterial growth for a better long-term performance of MFCs.…”

Section: Reducing the Cathode Deteriorationmentioning

confidence: 99%

“…Fouling and deformation of separator materials (e.g., membranes and various cloths) also impair the long-term stability of MFCs (Zhang X. et al, 2009;2010;Xu et al, 2012). The mechanism how separator fouling affects the performance of MFCs is very complex because physical, chemical, and biological interactions between the contaminants and the separator all occur simultaneously during the fouling process.…”

Section: Preventing the Fouling And Deformation Of Separatorsmentioning

confidence: 99%

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Microbial fuel cells for energy production from wastewaters: the way toward practical application

Liu

Cheng

2014

J. Zhejiang Univ. Sci. A

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Abstract:Much energy is stored in wastewaters. How to efficiently capture this energy is of great significance for meeting the world's energy needs, reducing wastewater handling costs and increasing the sustainability of wastewater treatment. The microbial fuel cell (MFC) is a recently developed biotechnology for electrical energy recovery from the organic pollutants in wastewaters. MFCs hold great promise for sustainable wastewater treatment. However, at present there is still much research needed before the MFC technique can be practically applied in the real world. In this review, we analyze the opportunities and key challenges for MFCs to achieve sustainability in wastewater treatment. We especially discuss the problems and challenges for scaling up the MFC systems; this is the most critical issue for realizing the practical implementation of this technique. In order to achieve sustainability, MFCs may also be combined with other techniques to yield high effluent quality or to recover more commercial value (i.e., by producing energy-rich or high value chemicals) from wastewaters. However, research in this area is still on-going and many problems need to be settled before real-world application. Advances are required in respect of efficiency, economic feasibility, system stability, and reliability.

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“…In this case, Nafion used in the MFCs is not an efficient proton specific membrane but actually a cation specific membrane (Rozendal et al, 2006). Subsequent studies have implied that anion-exchange or bipolar membranes has better properties than cation exchange membranes regarding to cell performance (Zhang et al, 2009). Two promising applications of MFCs in the future are wastewater treatment and electricity generation (Feng et al, 2008 andKaturi &Scott, 2010).…”

Section: Microbial Fuel Cellsmentioning

confidence: 99%