Duty cycling influences current generation in multi-anode environmental microbial fuel cells.

Improving microbial fuel cell (MFC) performance continues to be the subject of research, yet the role of operating conditions, specifically duty cycling, on MFC performance has been modestly addressed. We present a series of studies in which we use a 15-anode environmental MFC to explore how duty cycling (variations in the time an anode is connected) influences cumulative charge, current, and microbial composition. The data reveal particular switching intervals that result in the greatest time-normalized current. When disconnection times are sufficiently short, there is a striking decrease in current due to an increase in the overall electrode reaction resistance. This was observed over a number of whole cell potentials. Based on these results, we posit that replenishment of depleted electron donors within the biofilm and surrounding diffusion layer is necessary for maximum charge transfer, and that proton flux may be not limiting in the highly buffered aqueous phases that are common among environmental MFCs. Surprisingly, microbial diversity analyses found no discernible difference in gross community composition among duty cycling treatments, suggesting that duty cycling itself has little or no effect. Such duty cycling experiments are valuable in determining which factors govern performance of bioelectrochemical systems and might also be used to optimize field-deployed systems.

[1]  Shelley Brown,et al.  High current generation coupled to caustic production using a lamellar bioelectrochemical system. , 2010, Environmental science & technology.

[2]  Boris Tartakovsky,et al.  Microbial fuel cell operation with intermittent connection of the electrical load , 2012 .

[3]  E. E. L O G A N Microbial Fuel Cells : Methodology and Technology † , 2022 .

[4]  William A. Walters,et al.  QIIME allows analysis of high-throughput community sequencing data , 2010, Nature Methods.

[5]  P. N. Sarma,et al.  Saccharomyces cerevisiae as anodic biocatalyst for power generation in biofuel cell: influence of redox condition and substrate load. , 2011, Bioresource technology.

[6]  W. Liesack,et al.  Elemental Sulfur and Thiosulfate Disproportionation by Desulfocapsa sulfoexigens sp. nov., a New Anaerobic Bacterium Isolated from Marine Surface Sediment , 1998, Applied and Environmental Microbiology.

[7]  Abraham Esteve-Núñez,et al.  Electrochemical insight into the mechanism of electron transport in biofilms of Geobacter sulfurreducens , 2011 .

[8]  D. Newman,et al.  Extracellular electron transfer , 2001, Cellular and Molecular Life Sciences CMLS.

[9]  E. Roden,et al.  Enzymatic iron and uranium reduction by sulfate-reducing bacteria , 1993 .

[10]  D. Lovley,et al.  Novel Processes for Anaerobic Sulfate Production from Elemental Sulfur by Sulfate-Reducing Bacteria , 1994, Applied and environmental microbiology.

[11]  Allen J. Bard,et al.  Electrochemical Methods: Fundamentals and Applications , 1980 .

[12]  Jeffrey A. Gralnick,et al.  Shewanella oneidensis MR-1 Uses Overlapping Pathways for Iron Reduction at a Distance and by Direct Contact under Conditions Relevant for Biofilms , 2005, Applied and Environmental Microbiology.

[13]  Bruce E. Logan,et al.  Electricity Production from Steam-Exploded Corn Stover Biomass , 2006 .

[14]  Alice Dohnalkova,et al.  Electrically conductive bacterial nanowires produced by Shewanella oneidensis strain MR-1 and other microorganisms. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[15]  Willy Verstraete,et al.  Microbial ecology meets electrochemistry: electricity-driven and driving communities , 2007, The ISME Journal.

[16]  D. R. Bond,et al.  Shewanella secretes flavins that mediate extracellular electron transfer , 2008, Proceedings of the National Academy of Sciences.

[17]  Z. Lewandowski,et al.  Intermittent energy harvesting improves the performance of microbial fuel cells. , 2009, Environmental science & technology.

[18]  P. Liang,et al.  Alternate charging and discharging of capacitor to enhance the electron production of bioelectrochemical systems. , 2011, Environmental science & technology.

[19]  Han-Qing Yu,et al.  Enhanced reductive degradation of methyl orange in a microbial fuel cell through cathode modification with redox mediators , 2010, Applied Microbiology and Biotechnology.

[20]  C. Buisman,et al.  Towards practical implementation of bioelectrochemical wastewater treatment. , 2008, Trends in biotechnology.

[21]  B. Logan,et al.  Brewery wastewater treatment using air-cathode microbial fuel cells , 2008, Applied Microbiology and Biotechnology.

[22]  N. Uria,et al.  Transient storage of electrical charge in biofilms of Shewanella oneidensis MR-1 growing in a microbial fuel cell. , 2011, Environmental science & technology.

[23]  Peter R Girguis,et al.  Quantitative population dynamics of microbial communities in plankton-fed microbial fuel cells , 2009, The ISME Journal.

[24]  Frank J. Millero,et al.  Distribution of alkalinity in the surface waters of the major oceans , 1998 .

[25]  G. Premier,et al.  Sustainable wastewater treatment: how might microbial fuel cells contribute. , 2010, Biotechnology advances.

[26]  Derek R. Lovley,et al.  Biofilm and Nanowire Production Leads to Increased Current in Geobacter sulfurreducens Fuel Cells , 2006, Applied and Environmental Microbiology.

[27]  F. Millero Thermodynamics of the carbon dioxide system in the oceans , 1995 .

[28]  W. Verstraete,et al.  Microbial phenazine production enhances electron transfer in biofuel cells. , 2005, Environmental science & technology.

[29]  D. Lowy,et al.  Harnessing microbially generated power on the seafloor , 2002, Nature Biotechnology.

[30]  Zhen He,et al.  An upflow microbial fuel cell with an interior cathode: assessment of the internal resistance by impedance spectroscopy. , 2006, Environmental science & technology.

[31]  Derek R. Lovley,et al.  Novel strategy for three-dimensional real-time imaging of microbial fuel cell communities: monitoring the inhibitory effects of proton accumulation within the anode biofilm , 2009 .

[32]  D. Lowy,et al.  Harvesting energy from the marine sediment-water interface II. Kinetic activity of anode materials. , 2006, Biosensors & bioelectronics.

[33]  Prathap Parameswaran,et al.  Selecting anode-respiring bacteria based on anode potential: phylogenetic, electrochemical, and microscopic characterization. , 2009, Environmental science & technology.

[34]  D. R. Bond,et al.  Electron Transfer by Desulfobulbus propionicus to Fe(III) and Graphite Electrodes , 2004, Applied and Environmental Microbiology.

[35]  D. Pant,et al.  A review of the substrates used in microbial fuel cells (MFCs) for sustainable energy production. , 2010, Bioresource technology.

[36]  E. Cortón,et al.  Archaea-based microbial fuel cell operating at high ionic strength conditions , 2011, Extremophiles.

[37]  James R. Knight,et al.  Genome sequencing in microfabricated high-density picolitre reactors , 2005, Nature.

[38]  Hong Liu,et al.  Sustainable power generation in microbial fuel cells using bicarbonate buffer and proton transfer mechanisms. , 2008, Environmental science & technology.

[39]  K. Rabaey,et al.  Microbial electrosynthesis — revisiting the electrical route for microbial production , 2010, Nature Reviews Microbiology.

[40]  F C Walsh,et al.  Biofuel cells and their development. , 2006, Biosensors & bioelectronics.

[41]  R. Ramasamy,et al.  Impact of initial biofilm growth on the anode impedance of microbial fuel cells , 2008, Biotechnology and bioengineering.

[42]  Regina A. O'Neil,et al.  Microbial Communities Associated with Electrodes Harvesting Electricity from a Variety of Aquatic Sediments , 2004, Microbial Ecology.

[43]  Kaichang Li,et al.  Electricity production from twelve monosaccharides using microbial fuel cells , 2008 .

[44]  H. Hamelers,et al.  Performance of single chamber biocatalyzed electrolysis with different types of ion exchange membranes. , 2007, Water research.

[45]  Haluk Beyenal,et al.  Wireless sensors powered by microbial fuel cells. , 2005, Environmental science & technology.

[46]  T. Richard,et al.  Substrate-enhanced microbial fuel cells for improved remote power generation from sediment-based systems. , 2007, Environmental science & technology.

[47]  Leonard M. Tender,et al.  Microbial fuel cell energy from an ocean cold seep , 2006 .

[48]  Peter Kauffman,et al.  The first demonstration of a microbial fuel cell as a viable power supply: Powering a meteorological buoy , 2008 .

[49]  W. Verstraete,et al.  Biofuel Cells Select for Microbial Consortia That Self-Mediate Electron Transfer , 2004, Applied and Environmental Microbiology.

[50]  Bruce E Rittmann,et al.  Proton transport inside the biofilm limits electrical current generation by anode‐respiring bacteria , 2008, Biotechnology and bioengineering.

[51]  L. Tender,et al.  Harvesting Energy from the Marine Sediment−Water Interface , 2001 .

[52]  B. Logan,et al.  Electricity-producing bacterial communities in microbial fuel cells. , 2006, Trends in microbiology.

[53]  Kazuya Watanabe,et al.  Electron shuttles in biotechnology. , 2009, Current opinion in biotechnology.

[54]  Tingyue Gu,et al.  A state of the art review on microbial fuel cells: A promising technology for wastewater treatment and bioenergy. , 2007, Biotechnology advances.

[55]  Helen K. White,et al.  Sustainable energy from deep ocean cold seeps , 2008 .

[56]  B. Logan,et al.  Simultaneous wastewater treatment and biological electricity generation. , 2005, Water science and technology : a journal of the International Association on Water Pollution Research.

[57]  Mark E Nielsen,et al.  Enhanced power from chambered benthic microbial fuel cells. , 2007, Environmental science & technology.

[58]  Bruce E. Logan,et al.  Scale-up of membrane-free single-chamber microbial fuel cells , 2008 .

[59]  Haluk Beyenal,et al.  Scaling up microbial fuel cells. , 2008, Environmental science & technology.

[60]  K. Scott,et al.  Power from marine sediment fuel cells: the influence of anode material , 2008 .

[61]  H. May,et al.  Sustained generation of electricity by the spore-forming, Gram-positive, Desulfitobacterium hafniense strain DCB2 , 2007, Applied Microbiology and Biotechnology.

[62]  Mark E Nielsen,et al.  Influence of substrate on electron transfer mechanisms in chambered benthic microbial fuel cells. , 2009, Environmental science & technology.

[63]  Byoung-Chan Kim,et al.  Selection of a variant of Geobacter sulfurreducens with enhanced capacity for current production in microbial fuel cells. , 2009, Biosensors & bioelectronics.

[64]  A. K. Shukla,et al.  Biological fuel cells and their applications , 2004 .

[65]  P. Girguis,et al.  Harnessing energy from marine productivity using bioelectrochemical systems. , 2010, Current opinion in biotechnology.

[66]  Hyung-Sool Lee,et al.  Effects of substrate diffusion and anode potential on kinetic parameters for anode-respiring bacteria. , 2009, Environmental science & technology.