Sequential anode–cathode configuration improves cathodic oxygen reduction and effluent quality of microbial fuel cells

Freguia, Stefano; Rabaey, Korneel; Yuan, Zhiguo; Keller, Jürg

doi:10.1016/j.watres.2007.10.007

Cited by 185 publications

(97 citation statements)

References 21 publications

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“…A way to prevent this pH gradient is either to take out the membrane Liu and Logan 2004) or to pump the anolyte to the cathode to guarantee mixing (Freguia et al 2008a). Although it has been shown that both methods prevent the pH gradient to develop, it also causes substrate/product crossover giving unwanted side reactions and products.…”

Section: Implications For Designmentioning

confidence: 99%

New applications and performance of bioelectrochemical systems

Hamelers

Heijne

Sleutels

et al. 2009

Appl Microbiol Biotechnol

249

136

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Bioelectrochemical systems (BESs) are emerging technologies which use microorganisms to catalyze the reactions at the anode and/or cathode. BES research is advancing rapidly, and a whole range of applications using different electron donors and acceptors has already been developed. In this mini review, we focus on technological aspects of the expanding application of BESs. We will analyze the anode and cathode half-reactions in terms of their standard and actual potential and report the overpotentials of these half-reactions by comparing the reported potentials with their theoretical potentials. When combining anodes with cathodes in a BES, new bottlenecks and opportunities arise. For application of BESs, it is crucial to lower the internal energy losses and increase productivity at the same time. Membranes are a crucial element to obtain high efficiencies and pure products but increase the internal resistance of BESs. The comparison between production of fuels and chemicals in BESs and in present production processes should gain more attention in future BES research. By making this comparison, it will become clear if the scope of BESs can and should be further developed into the field of biorefineries.

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Section: Implications For Designmentioning

confidence: 99%

New applications and performance of bioelectrochemical systems

Hamelers

Heijne

Sleutels

et al. 2009

Appl Microbiol Biotechnol

249

136

View full text Add to dashboard Cite

show abstract

“…The electric voltage is proportional to the electron-driving force from anode to cathode, and the electric current is proportional to the reducing power generated by bacterial cells. The solar cells induce the electron-driving force from anode to cathode, by which the oxidation reaction coupled with bacterial catabolism may be activated in the anode and the reduction reaction of oxygen with protons and electrons may be activated in the cathode [10,39].…”

Section: Discussionmentioning

confidence: 99%

“…The combination of a Mn(IV)-modified anode and a Fe(III)-modified cathode may be ideal for composing an MFC without an electron mediator and oxidant, but not one from which catholyte aeration can be excluded [4,29,32]. In order to compose an MFC without catholyte aeration, the cathode has to function as a catalyst for the electrochemical reaction of protons, electrons, and oxygen [10], and as a redox barrier to conserve the potential difference between the anode and cathode. Graphite felt, to which neutral red (an electron mediator) is immobilized to catalyze electron transfer from bacterial cells to the electrode [30,36], generally has been used as both the anode and cathode, but it is difficult to modify membranes with this material because of its soft and weak structure.…”

mentioning

confidence: 99%

Electricity Generation Coupled with Wastewater Treatment Using a Microbial Fuel Cell Composed of a Modified Cathode with a Ceramic Membrane and Cellulose Acetate Film

Seo

Lee²,

Hwang³

et al. 2009

J.Microbiol.Biotechnol

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“…The graphite granules have diameters of 1.5-6 mm and a porosity of 45%, leading to a mean nominal surface area of 1,000 cm 2 in each compartment (Freguia et al 2008). …”

Section: Two-compartment Electrochemical Reactor Design and Operationmentioning

confidence: 99%

A novel electrochemical process for the recovery and recycling of ferric chloride from precipitation sludge

et al. 2014

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During wastewater treatment and drinking water production, significant amounts of ferric sludge (comprising ferric oxy-hydroxides and FePO 4 ) are generated that require disposal. This practice has a major impact on the overall treatment cost as a result of both chemical addition and the disposal of the generated chemical sludge.Iron sulfide (FeS) precipitation via sulfide addition to ferric phosphate (FePO 4 ) sludge has been proven as an effective process for phosphate recovery. In turn, iron and sulfide could potentially be recovered from the FeS sludge, and recycled back to the process. In this work, a novel process was investigated at lab scale for the recovery of soluble iron and sulfide from FeS sludge. Soluble iron is regenerated electrochemically at a graphite anode, while sulfide is recovered at the cathode of the same electrochemical cell. Up to 60±18% soluble Fe and 46±11% sulfide were recovered on graphite granules for up-stream reuse. Peak current densities of 9.5 ± 4.2 A m -2 and minimum power requirements of 2.4 ± 0.5 kWh kg Fe -1 were reached with real full strength FeS suspensions. Multiple consecutive runs of the electrochemical process were performed, leading to the successful demonstration of an integrated process, comprising FeS formation/separation and ferric/sulfide electrochemical regeneration.

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Sequential anode–cathode configuration improves cathodic oxygen reduction and effluent quality of microbial fuel cells

Cited by 185 publications

References 21 publications

New applications and performance of bioelectrochemical systems

New applications and performance of bioelectrochemical systems

Electricity Generation Coupled with Wastewater Treatment Using a Microbial Fuel Cell Composed of a Modified Cathode with a Ceramic Membrane and Cellulose Acetate Film

A novel electrochemical process for the recovery and recycling of ferric chloride from precipitation sludge

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