All Stories

  1. Electrochemistry for Biofuel Generation: Transformation of Fatty Acids and Triglycerides to Diesel-Like Olefin/Ether Mixtures and Olefins

    Article • ChemSusChem, February 2015, Wiley

    Professor Uwe Schröder

  2. Microbial electrochemistry and technology: terminology and classification

    Article • Energy & Environmental Science, January 2015, Royal Society of Chemistry

    Professor Uwe Schröder

  3. Electrochemistry of Immobilized Particles and Droplets

    Article • January 2015, Springer Science + Business Media

    Professor Uwe Schröder

  4. Electrochemistry for the generation of renewable chemicals: electrochemical conversion of levulinic acid

    Article • RSC Advances, January 2015, Royal Society of Chemistry

    Professor Uwe Schröder

  5. Does it have to be carbon? Metal anodes in microbial fuel cells and related bioelectrochemical systems

    Article • Energy & Environmental Science, January 2015, Royal Society of Chemistry

    Professor Uwe Schröder

  6. Reactor concepts for bioelectrochemical syntheses and energy conversion

    Article • Trends in Biotechnology, December 2014, Elsevier

    Professor Uwe Schröder, Dr DIrk Holtmann

  7. Biological Fuel Cells: Cardinal Advances and Critical Challenges

    Article • ChemElectroChem, November 2014, Wiley

    Professor Uwe Schröder

  8. Immobilized Particles

    Article • September 2014, Springer Science + Business Media

    Professor Uwe Schröder

  9. The Experiment

    Article • September 2014, Springer Science + Business Media

    Professor Uwe Schröder

  10. Immobilized Droplets

    Article • September 2014, Springer Science + Business Media

    Professor Uwe Schröder

  11. Electrodes with Immobilized Particles and Droplets: Three-Phase Electrodes

    Article • September 2014, Springer Science + Business Media

    Professor Uwe Schröder

  12. Hyphenated Techniques

    Article • September 2014, Springer Science + Business Media

    Professor Uwe Schröder

  13. Evaluating the effects of scaling up on the performance of bioelectrochemical systems using a technical scale microbial electrolysis cell

    Article • Bioresource Technology, July 2014, Elsevier

    Professor Uwe Schröder

  14. From Microbial Bioelectrocatalysis to Microbial Bioelectrochemical Systems

    Article • March 2014, Wiley

    Professor Uwe Schröder

  15. Metabolic Efficiency of Geobacter sulfurreducens Growing on Anodes with Different Redox Potentials

    Article • Current Microbiology, February 2014, Springer Science + Business Media

    Professor Uwe Schröder

  16. Activated carbon nanofibers (ACNF) as cathode for single chamber microbial fuel cells (SCMFCs)

    Article • Journal of Power Sources, December 2013, Elsevier

    Professor Uwe Schröder

  17. Electron transfer and biofilm formation of Shewanella putrefaciens as function of anode potential

    Article • Bioelectrochemistry, October 2013, Elsevier

    Professor Uwe Schröder

  18. Mikroben unter Strom

    Article • Biologie in unserer Zeit, April 2013, Wiley

    Professor Uwe Schröder

  19. Selbstorganisierte Enzymnetzwerke - ein Weg zu komplexen bioelektrokatalytischen Systemen

    Article • Angewandte Chemie, February 2013, Wiley

    Professor Uwe Schröder

  20. Self-Assembling Enzyme Networks-A New Path towards Multistep Bioelectrocatalytic Systems

    Article • Angewandte Chemie International Edition, February 2013, Wiley

    Professor Uwe Schröder

  21. Unraveling the Interfacial Electron Transfer Dynamics of Electroactive Microbial Biofilms Using Surface-Enhanced Raman Spectroscopy

    Article • ChemSusChem, February 2013, Wiley

    Professor Uwe Schröder

  22. Electrochemistry for biofuel generation: production of furans by electrocatalytic hydrogenation of furfurals

    Article • Energy & Environmental Science, January 2013, Royal Society of Chemistry

    Professor Uwe Schröder

  23. Hydrothermal production of furfural from xylose and xylan as model compounds for hemicelluloses

    Article • RSC Advances, January 2013, Royal Society of Chemistry

    Professor Uwe Schröder

  24. From the test-tube to the test-engine: assessing the suitability of prospective liquid biofuel compounds

    Article • RSC Advances, January 2013, Royal Society of Chemistry

    Professor Uwe Schröder

  25. Hydrothermal liquefaction of cellulose in subcritical water—the role of crystallinity on the cellulose reactivity

    Article • RSC Advances, January 2013, Royal Society of Chemistry

    Professor Uwe Schröder

  26. On the removal of sulfonamides using microbial bioelectrochemical systems

    Article • Electrochemistry Communications, January 2013, Elsevier

    Professor Uwe Schröder

  27. Comparative study of IVB–VIB transition metal compound electrocatalysts for the hydrogen evolution reaction

    Article • Applied Catalysis B Environment and Energy, September 2012, Elsevier

    Professor Uwe Schröder

  28. Von in vitro zu in vivo - Biobrennstoffzellen werden erwachsen

    Article • Angewandte Chemie, June 2012, Wiley

    Professor Uwe Schröder

  29. From In Vitro to In Vivo-Biofuel Cells Are Maturing

    Article • Angewandte Chemie International Edition, June 2012, Wiley

    Professor Uwe Schröder

  30. Editorial: Microbial Fuel Cells and Microbial Electrochemistry: Into the Next Century!

    Article • ChemSusChem, June 2012, Wiley

    Professor Uwe Schröder

  31. Cover Picture: Microbial Fuel Cells and Microbial Electrochemistry: Into the Next Century! (ChemSusChem 6/2012)

    Article • ChemSusChem, June 2012, Wiley

    Professor Uwe Schröder

  32. Microwave-assisted hydrothermal degradation of fructose and glucose in subcritical water

    Article • Biomass and Bioenergy, April 2012, Elsevier

    Professor Uwe Schröder

  33. Stainless steel mesh supported nitrogen-doped carbon nanofibers for binder-free cathode in microbial fuel cells

    Article • Biosensors and Bioelectronics, April 2012, Elsevier

    Professor Uwe Schröder

  34. A Three-Dimensionally Ordered Macroporous Carbon Derived From a Natural Resource as Anode for Microbial Bioelectrochemical Systems

    Article • ChemSusChem, March 2012, Wiley

    Professor Uwe Schröder

  35. Electrochemistry for biofuel generation: Electrochemical conversion of levulinic acid to octane

    Article • Energy & Environmental Science, January 2012, Royal Society of Chemistry

    Falk Harnisch, Professor Uwe Schröder

  36. Layered corrugated electrode macrostructures boost microbial bioelectrocatalysis

    Article • Energy & Environmental Science, January 2012, Royal Society of Chemistry

    Professor Uwe Schröder

  37. Biomass to Biofuels: Strategies for Global Industries

    Article • CLEAN - Soil Air Water, November 2011, Wiley

    Professor Uwe Schröder

  38. Effect of fiber diameter on the behavior of biofilm and anodic performance of fiber electrodes in microbial fuel cells

    Article • Bioresource Technology, November 2011, Elsevier

    Professor Uwe Schröder

  39. Electrospun carbon fiber mat with layered architecture for anode in microbial fuel cells

    Article • Electrochemistry Communications, October 2011, Elsevier

    Professor Uwe Schröder

  40. Electroactive mixed culture derived biofilms in microbial bioelectrochemical systems: The role of pH on biofilm formation, performance and composition

    Article • Bioresource Technology, October 2011, Elsevier

    Professor Uwe Schröder

  41. Selbstorganisierte Enzymarrays - ein Weg hin zu komplexen bioelektrokatalytischen Systemen

    Article • Angewandte Chemie, July 2011, Wiley

    Professor Uwe Schröder

  42. Self-Assembling Enzyme Arrays en Route to Multistep Bioelectrocatalytic Systems

    Article • Angewandte Chemie International Edition, July 2011, Wiley

    Professor Uwe Schröder

  43. Comments on “Electricity generation by Enterobacter cloacae SU-1 in mediator less microbial fuel cell” by Samrot et al., Int. J. Hydrogen Energy, 35 (15) 2010, 7723–7729

    Article • International Journal of Hydrogen Energy, July 2011, Elsevier

    Professor Uwe Schröder

  44. Enhanced Activity of Non-Noble Metal Electrocatalysts for the Oxygen Reduction Reaction Using Low Temperature Plasma Treatment

    Article • Plasma Processes and Polymers, June 2011, Wiley

    Professor Uwe Schröder

  45. Cyclic voltammetric analysis of the electron transfer of Shewanella oneidensis MR-1 and nanofilament and cytochrome knock-out mutants

    Article • Bioelectrochemistry, June 2011, Elsevier

    Professor Uwe Schröder

  46. Discover the possibilities: microbial bioelectrochemical systems and the revival of a 100-year–old discovery

    Article • Journal of Solid State Electrochemistry, May 2011, Springer Science + Business Media

    Professor Uwe Schröder

  47. Spektroelektrochemische In-situ-Untersuchung von elektrokatalytischen mikrobiellen Biofilmen mit oberflächenverstärkter Resonanz-Raman-Spektroskopie

    Article • Angewandte Chemie, February 2011, Wiley

    Professor Uwe Schröder

  48. In Situ Spectroelectrochemical Investigation of Electrocatalytic Microbial Biofilms by Surface-Enhanced Resonance Raman Spectroscopy

    Article • Angewandte Chemie International Edition, February 2011, Wiley

    Professor Uwe Schröder

  49. Subcritical Water as Reaction Environment: Fundamentals of Hydrothermal Biomass Transformation

    Article • ChemSusChem, February 2011, Wiley

    Professor Uwe Schröder

  50. Electrospun and solution blown three-dimensional carbon fiber nonwovens for application as electrodes in microbial fuel cells

    Article • Energy & Environmental Science, January 2011, Royal Society of Chemistry

    Professor Uwe Schröder

  51. Revealing the electrochemically driven selection in natural community derived microbial biofilms using flow-cytometry

    Article • Energy & Environmental Science, January 2011, Royal Society of Chemistry

    Professor Uwe Schröder

  52. Electroactive mixed culture biofilms in microbial bioelectrochemical systems: The role of temperature for biofilm formation and performance

    Article • Biosensors and Bioelectronics, October 2010, Elsevier

    Professor Uwe Schröder

  53. Keeping intermediates on the track: towards tailored metabolons for bioelectrocatalysis

    Article • Biofuels, September 2010, Taylor & Francis

    Professor Uwe Schröder

  54. Toxicity Response of Electroactive Microbial Biofilms-A Decisive Feature for Potential Biosensor and Power Source Applications

    Article • ChemPhysChem, July 2010, Wiley

    Professor Uwe Schröder

  55. The study of electrochemically active microbial biofilms on different carbon-based anode materials in microbial fuel cells

    Article • Biosensors and Bioelectronics, May 2010, Elsevier

    Professor Uwe Schröder

  56. Photomicrobial Solar and Fuel Cells

    Article • Electroanalysis, March 2010, Wiley

    Professor Uwe Schröder

  57. From MFC to MXC: chemical and biological cathodes and their potential for microbial bioelectrochemical systems

    Article • Chemical Society Reviews, January 2010, Royal Society of Chemistry

    Professor Uwe Schröder

  58. Effects of substrate and metabolite crossover on the cathodic oxygen reduction reaction in microbial fuel cells: Platinum vs. iron(II) phthalocyanine based electrodes

    Article • Electrochemistry Communications, November 2009, Elsevier

    Professor Uwe Schröder

  59. Selectivity versus Mobility: Separation of Anode and Cathode in Microbial Bioelectrochemical Systems

    Article • ChemSusChem, October 2009, Wiley

    Professor Uwe Schröder

  60. Comparative study on the performance of pyrolyzed and plasma-treated iron(II) phthalocyanine-based catalysts for oxygen reduction in pH neutral electrolyte solutions

    Article • Journal of Power Sources, August 2009, Elsevier

    Professor Uwe Schröder

  61. Electrocatalytic and corrosion behaviour of tungsten carbide in near-neutral pH electrolytes

    Article • Applied Catalysis B Environment and Energy, March 2009, Elsevier

    Professor Uwe Schröder

  62. An improved microbial fuel cell with laccase as the oxygen reduction catalyst

    Article • Energy & Environmental Science, January 2009, Royal Society of Chemistry

    Professor Uwe Schröder

  63. Improvement of the anodic bioelectrocatalytic activity of mixed culture biofilms by a simple consecutive electrochemical selection procedure

    Article • Biosensors and Bioelectronics, December 2008, Elsevier

    Professor Uwe Schröder

  64. From Wastewater to Hydrogen: Biorefineries Based on Microbial Fuel-Cell Technology

    Article • ChemSusChem, April 2008, Wiley

    Professor Uwe Schröder

  65. The Suitability of Monopolar and Bipolar Ion Exchange Membranes as Separators for Biological Fuel Cells

    Article • Environmental Science & Technology, March 2008, American Chemical Society (ACS)

    Professor Uwe Schröder

  66. On the use of cyclic voltammetry for the study of anodic electron transfer in microbial fuel cells

    Article • Energy & Environmental Science, January 2008, Royal Society of Chemistry

    Professor Uwe Schröder

  67. Evaluation of catalytic properties of tungsten carbide for the anode of microbial fuel cells

    Article • Applied Catalysis B Environment and Energy, July 2007, Elsevier

    Professor Uwe Schröder

  68. Anodic electron transfer mechanisms in microbial fuel cells and their energy efficiency

    Article • Physical Chemistry Chemical Physics, January 2007, Royal Society of Chemistry

    Professor Uwe Schröder

  69. Interfacing Electrocatalysis and Biocatalysis with Tungsten Carbide: A High-Performance, Noble-Metal-Free Microbial Fuel Cell

    Article • Angewandte Chemie, October 2006, Wiley

    Professor Uwe Schröder

  70. Microbial Fuel Cells:  Methodology and Technology †

    Article • Environmental Science & Technology, September 2006, American Chemical Society (ACS)

    Professor Uwe Schröder

  71. Challenges and Constraints of Using Oxygen Cathodes in Microbial Fuel Cells

    Article • Environmental Science & Technology, September 2006, American Chemical Society (ACS)

    Professor Uwe Schröder

  72. Investigation of the electrocatalytic oxidation of formate and ethanol at platinum black under microbial fuel cell conditions

    Article • Journal of Solid State Electrochemistry, May 2006, Springer Science + Business Media

    Professor Uwe Schröder

  73. Application of pyrolysed iron(II) phthalocyanine and CoTMPP based oxygen reduction catalysts as cathode materials in microbial fuel cells

    Article • Electrochemistry Communications, December 2005, Elsevier

    Professor Uwe Schröder

  74. Electrochemistry of Immobilized Particles and Droplets By Fritz Scholz, Uwe Schröder (Universität Greifswald, Germany), and Rubin Gulaboski (Universidade do Porto, Portugal). Springer:  Berlin, Heidelberg, New York. 2005. xiv + 290 pp. $129.00. ISBN 3-...

    Article • Journal of the American Chemical Society, December 2005, American Chemical Society (ACS)

    Professor Uwe Schröder

  75. Utilizing the green alga Chlamydomonas reinhardtii for microbial electricity generation: a living solar cell

    Article • Applied Microbiology and Biotechnology, October 2005, Springer Science + Business Media

    Professor Uwe Schröder

  76. In Situ Electrooxidation of Photobiological Hydrogen in a Photobioelectrochemical Fuel Cell Based on Rhodobacter sphaeroides

    Article • Environmental Science & Technology, August 2005, American Chemical Society (ACS)

    Professor Uwe Schröder

  77. Fluorinated polyanilines as superior materials for electrocatalytic anodes in bacterial fuel cells

    Article • Electrochemistry Communications, June 2004, Elsevier

    Professor Uwe Schröder

  78. Bacterial batteries

    Article • Nature Biotechnology, October 2003, Springer Science + Business Media

    Professor Uwe Schröder

  79. A Generation of Microbial Fuel Cells with Current Outputs Boosted by More Than One Order of Magnitude

    Article • Angewandte Chemie International Edition, June 2003, Wiley

    Professor Uwe Schröder

  80. Voltammetry of Electroactive Oil Droplets:  Electrochemically-Induced Ion Insertion, Expulsion and Reaction Processes at Microdroplets of N,N,N ‘ ,N ‘ - Tetraalkyl- para - phenylenediamines (TRPD, R = n -Butyl, n- Hexyl, n- Heptyl and n- Nonyl)

    Article • The Journal of Physical Chemistry, September 2002, American Chemical Society (ACS)

    Professor Uwe Schröder

  81. Probing Thermodynamic Aspects of Electrochemically Driven Ion-Transfer Processes Across Liquid|Liquid Interfaces:  Pure versus Diluted Redox Liquids

    Article • The Journal of Physical Chemistry, August 2002, American Chemical Society (ACS)

    Professor Uwe Schröder

  82. Electrochemical Analysis of Solids. A Review

    Article • Collection of Czechoslovak Chemical Communications, January 2002, Institute of Organic Chemistry & Biochemistry

    Professor Uwe Schröder

  83. Electrochemically Driven Ion Insertion Processes across Liquid|Liquid Boundaries:  Neutral versus Ionic Redox Liquids

    Article • The Journal of Physical Chemistry, February 2001, American Chemical Society (ACS)

    Professor Uwe Schröder

  84. Ionic liquid modified electrodes. Unusual partitioning and diffusion effects of Fe(CN)64−/3− in droplet and thin layer deposits of 1-methyl-3-(2,6-(S)-dimethylocten-2-yl)-imidazolium tetrafluoroborate

    Article • Journal of Electroanalytical Chemistry, November 2000, Elsevier

    Professor Uwe Schröder

  85. Voltammetry of Electroactive Oil Droplets. Part II: Comparison of Experimental and Simulation Data for Coupled Ion and Electron Insertion Processes and Evidence for Microscale Convection

    Article • Electroanalysis, September 2000, Wiley

    Professor Uwe Schröder

  86. Modelling of solid state voltammetry of immobilized microcrystals assuming an initiation of the electrochemical reaction at a three-phase junction

    Article • Journal of Solid State Electrochemistry, July 2000, Springer Science + Business Media

    Professor Uwe Schröder

  87. The Solid-State Electrochemistry of Metal Octacyanomolybdates, Octacyanotungstates, and Hexacyanoferrates Explained on the Basis of Dissolution and Reprecipitation Reactions, Lattice Structures, and Crystallinities

    Article • Inorganic Chemistry, March 2000, American Chemical Society (ACS)

    Professor Uwe Schröder

  88. Water-induced accelerated ion diffusion: voltammetric studies in 1-methyl-3-[2,6-(S)-dimethylocten-2-yl]imidazolium tetrafluoroborate, 1-butyl-3-methylimidazolium tetrafluoroborate and hexafluorophosphate ionic liquids

    Article • New Journal of Chemistry, January 2000, Royal Society of Chemistry

    Professor Uwe Schröder

  89. The electrochemical response of radiation defects of non-conducting materials An electrochemical access to age determinations

    Article • Journal of Electroanalytical Chemistry, March 1995, Elsevier

    Professor Uwe Schröder