ABSTRACTThe external resistance (Rext) of microbial fuel cells (MFCs) regulates both the anode availability as an electron acceptor and the electron flux through the circuit. We evaluated the effects ofRexton MFCs using acetate or glucose. The average current densities (I) ranged from 40.5 mA/m2(9,800 Ω) to 284.5 mA/m2(150 Ω) for acetate-fed MFCs (acetate-fed reactors [ARs]), with a corresponding anode potential (Ean) range of −188 to −4 mV (versus a standard hydrogen electrode [SHE]). For glucose-fed MFCs (glucose-fed reactors [GRs]),Iranged from 40.0 mA/m2(9,800 Ω) to 273.0 mA/m2(150 Ω), with a correspondingEanrange of −189 to −7 mV. ARs produced higher Coulombic efficiencies and energy efficiencies than GRs over all testedRextlevels because of electron and potential losses from glucose fermentation. Biogas production accounted for 14 to 18% of electron flux in GRs but only 0 to 6% of that in ARs. GRs produced similar levels of methane, regardless of theRext. However, total methane production in ARs increased asRextincreased, suggesting thatEanmight influence the competition for substrates between exoelectrogens and methanogens in ARs. An increase ofRextto 9,800 Ω significantly changed the anode bacterial communities for both ARs and GRs, while operating at 970 Ω and 150 Ω had little effect.DeltaproteobacteriaandBacteroideteswere the major groups found in anode communities in ARs and GRs.BetaproteobacteriaandGammaproteobacteriawere found only in ARs.Bacilliwere abundant only in GRs. The anode-methanogenic communities were dominated byMethanosaetaceae, with significantly lower numbers ofMethanomicrobiales. These results show thatRextaffects not only theEanand current generation but also the anode biofilm community and methanogenesis.
A grey box model of glucose fermentation and syntrophic oxidation in microbial fuel cells
