Carbon dioxide conversion to C1 - C2 compounds in a microbial electrosynthesis cell with in situ electrodeposition of nickel and iron

[1]  S. Omanovic,et al.  Nickel oxide on directly grown carbon nanofibers for energy storage applications , 2020, Journal of Applied Electrochemistry.

[2]  B. Tartakovsky,et al.  In-situ Electrodeposition of Nickel on a Biocathode to Enhance Methane Production from Carbon Dioxide in a Microbial Electrosynthesis System , 2020, ECS Transactions.

[3]  B. Tartakovsky,et al.  Combined energy storage and methane bioelectrosynthesis from carbon dioxide in a microbial electrosynthesis system , 2019 .

[4]  Mayur B. Kurade,et al.  Interspecies microbial nexus facilitated methanation of polysaccharidic wastes. , 2019, Bioresource technology.

[5]  Miguel Ángel López Zavala,et al.  Use of Cyclic Voltammetry to Describe the Electrochemical Behavior of a Dual-Chamber Microbial Fuel Cell , 2019, Energies.

[6]  A. Morán,et al.  Enhanced CO2 Conversion to Acetate through Microbial Electrosynthesis (MES) by Continuous Headspace Gas Recirculation , 2019, Energies.

[7]  N. Ren,et al.  Insights on acetate-ethanol fermentation by hydrogen-producing Ethanoligenens under acetic acid accumulation based on quantitative proteomics. , 2019, Environment international.

[8]  Renduo Zhang,et al.  Efficient reduction of nitrobenzene by sulfate-reducer enriched biocathode in microbial electrolysis cell. , 2019, The Science of the total environment.

[9]  B. Tartakovsky,et al.  On-line monitoring of heavy metals-related toxicity with a microbial fuel cell biosensor. , 2019, Biosensors & bioelectronics.

[10]  Kaiqin Xu,et al.  Electro-conversion of carbon dioxide (CO2) to low-carbon methane by bioelectromethanogenesis process in microbial electrolysis cells: The current status and future perspective. , 2019, Bioresource technology.

[11]  S. Omanovic,et al.  The influence of addition of iridium-oxide to nickel-molybdenum-oxide cathodes on the electrocatalytic activity towards hydrogen evolution in acidic medium and on the cathode deactivation resistance , 2019, Electrochimica Acta.

[12]  Bruce E Logan,et al.  Electroactive microorganisms in bioelectrochemical systems , 2019, Nature Reviews Microbiology.

[13]  Youcai Zhao,et al.  A comprehensive comparison of five different carbon-based cathode materials in CO2 electromethanogenesis: Long-term performance, cell-electrode contact behaviors and extracellular electron transfer pathways. , 2018, Bioresource technology.

[14]  Z. Lai,et al.  Porous Hollow Fiber Nickel Electrodes for Effective Supply and Reduction of Carbon Dioxide to Methane through Microbial Electrosynthesis , 2018, Advanced Functional Materials.

[15]  H. Gavala,et al.  Enrichment of syngas-converting mixed microbial consortia for ethanol production and thermodynamics-based design of enrichment strategies , 2018, Biotechnology for Biofuels.

[16]  J. Krömer,et al.  Microbial Electrosynthesis of Isobutyric, Butyric, Caproic Acids, and Corresponding Alcohols from Carbon Dioxide , 2018, ACS Sustainable Chemistry & Engineering.

[17]  K. Chae,et al.  Improvement in methanogenesis by incorporating transition metal nanoparticles and granular activated carbon composites in microbial electrolysis cells , 2017 .

[18]  B. Rittmann,et al.  Changes in Glucose Fermentation Pathways as a Response to the Free Ammonia Concentration in Microbial Electrolysis Cells. , 2017, Environmental science & technology.

[19]  C. Santoro,et al.  Three-dimensional graphene nanosheets as cathode catalysts in standard and supercapacitive microbial fuel cell , 2017, Journal of power sources.

[20]  Sebastià Puig,et al.  On the Edge of Research and Technological Application: A Critical Review of Electromethanogenesis , 2017, International journal of molecular sciences.

[21]  B. Li,et al.  Enhancing electron transfer by ferroferric oxide during the anaerobic treatment of synthetic wastewater with mixed organic carbon , 2017 .

[22]  Jianzhong Sun,et al.  The endophytic bacteria isolated from elephant grass (Pennisetum purpureum Schumach) promote plant growth and enhance salt tolerance of Hybrid Pennisetum , 2016, Biotechnology for Biofuels.

[23]  Wenzong Liu,et al.  Microbial network for waste activated sludge cascade utilization in an integrated system of microbial electrolysis and anaerobic fermentation , 2016, Biotechnology for Biofuels.

[24]  Abudukeremu Kadier,et al.  A comprehensive review of microbial electrolysis cells (MEC) reactor designs and configurations for sustainable hydrogen gas production , 2016 .

[25]  A. Guisasola,et al.  Microbial community analysis in a long-term membrane-less microbial electrolysis cell with hydrogen and methane production. , 2015, Bioelectrochemistry.

[26]  Y. Rafrafi,et al.  Importance of the hydrogen route in up-scaling electrosynthesis for microbial CO2 reduction , 2015 .

[27]  S. Tringe,et al.  Primer and platform effects on 16S rRNA tag sequencing , 2015, Front. Microbiol..

[28]  C. Buisman,et al.  Analysis of the mechanisms of bioelectrochemical methane production by mixed cultures , 2015 .

[29]  P. Hallenbeck,et al.  Recent Advances in Microbial Electrocatalysis , 2014, Electrocatalysis.

[30]  Yong Jiang,et al.  Removal of Sulfide and Production of Methane from Carbon Dioxide in Microbial Fuel Cells–Microbial Electrolysis Cell (MFCs–MEC) Coupled System , 2014, Applied Biochemistry and Biotechnology.

[31]  Uwe Schröder,et al.  Electron transfer and biofilm formation of Shewanella putrefaciens as function of anode potential. , 2013, Bioelectrochemistry.

[32]  M. Khan,et al.  Bioelectricity Generation from Palm Oil Mill Effluent in Microbial Fuel Cell Using Polacrylonitrile Carbon Felt as Electrode , 2013, Water, Air, & Soil Pollution.

[33]  Hubertus V. M. Hamelers,et al.  Microbial electrolysis cells for production of methane from CO2: long‐term performance and perspectives , 2012 .

[34]  Largus T. Angenent,et al.  Metabolite-based mutualism between Pseudomonas aeruginosaPA14 and Enterobacter aerogenes enhances current generation in bioelectrochemical systems , 2011 .

[35]  Mauro Majone,et al.  Bioelectrochemical reduction of CO(2) to CH(4) via direct and indirect extracellular electron transfer by a hydrogenophilic methanogenic culture. , 2010, Bioresource technology.

[36]  Uwe Schröder,et al.  On the use of cyclic voltammetry for the study of anodic electron transfer in microbial fuel cells , 2008 .

[37]  Boris Tartakovsky,et al.  Biocatalyzed hydrogen production in a continuous flow microbial fuel cell with a gas phase cathode , 2008 .

[38]  Bruce E Rittmann,et al.  Conduction‐based modeling of the biofilm anode of a microbial fuel cell , 2007, Biotechnology and bioengineering.

[39]  Byung Hong Kim,et al.  A novel electrochemically active and Fe(III)-reducing bacterium phylogenetically related to Clostridium butyricum isolated from a microbial fuel cell , 2001 .

[40]  F. Mcintosh,et al.  Effect of adding acetogenic bacteria on methane production by mixed rumen microorganisms , 1999 .

[41]  D. R. Woods,et al.  Acetone-butanol fermentation revisited , 1986 .

[42]  Sun Guodong,et al.  Impact of applied voltage on methane generation and microbial activities in an anaerobic microbial electrolysis cell (MEC) , 2016 .

[43]  Karsten Zengler,et al.  A new model for electron flow during anaerobic digestion: direct interspecies electron transfer to Methanosaeta for the reduction of carbon dioxide to methane , 2014 .

[44]  Tian Zhang,et al.  Improved cathode materials for microbial electrosynthesis , 2013 .

[45]  S. Sastry,et al.  Effect of moderate electric field frequency and growth stage on the cell membrane permeability of Lactobacillus acidophilus , 2009, Biotechnology progress.

[46]  William B. Whitman,et al.  Anabolic Pathways in Methanogens , 1993 .