| scholarly article | Q13442814 |
| P50 | author | David Beratan | Q42412342 |
| P2093 | author name string | Nicholas F Polizzi | |
| Spiros S Skourtis | |||
| P2860 | cites work | Protein electron transfer rates set by the bridging secondary and tertiary structure | Q44217832 |
| Electron transfer mechanisms. | Q47829458 | ||
| Conduction-based modeling of the biofilm anode of a microbial fuel cell. | Q50979263 | ||
| Tunable metallic-like conductivity in microbial nanowire networks | Q57265703 | ||
| Characterization of Shewanella oneidensis MtrC: a cell-surface decaheme cytochrome involved in respiratory electron transport to extracellular electron acceptors | Q80800490 | ||
| Free energy and temperature dependence of electron transfer at the metal-electrolyte interface | Q81231642 | ||
| Structure of a bacterial cell surface decaheme electron conduit | Q27667964 | ||
| Microbial electrosynthesis: feeding microbes electricity to convert carbon dioxide and water to multicarbon extracellular organic compounds | Q28290695 | ||
| Characterization of an electron conduit between bacteria and the extracellular environment | Q30157016 | ||
| Probing electron transfer mechanisms in Shewanella oneidensis MR-1 using a nanoelectrode platform and single-cell imaging. | Q30496814 | ||
| Electron transmission through molecules and molecular interfaces | Q30988611 | ||
| Mechanisms of electron transfer in two decaheme cytochromes from a metal-reducing bacterium | Q33302840 | ||
| Michaelis-Menten equation and detailed balance in enzymatic networks | Q33350930 | ||
| Electron flow through metalloproteins | Q33575739 | ||
| Direct exchange of electrons within aggregates of an evolved syntrophic coculture of anaerobic bacteria. | Q33762052 | ||
| Electrical transport along bacterial nanowires from Shewanella oneidensis MR-1. | Q34241189 | ||
| Engineering of a synthetic electron conduit in living cells | Q34320464 | ||
| Proton-coupled electron flow in protein redox machines | Q34423826 | ||
| Electrically conductive bacterial nanowires produced by Shewanella oneidensis strain MR-1 and other microorganisms | Q34548796 | ||
| Electron transfer between biological molecules by thermally activated tunneling | Q35113463 | ||
| Electron transfer at the microbe-mineral interface: a grand challenge in biogeochemistry | Q37171052 | ||
| Steering electrons on moving pathways | Q37394124 | ||
| Exoelectrogenic bacteria that power microbial fuel cells | Q37426276 | ||
| Fluctuations in biological and bioinspired electron-transfer reactions | Q37700731 | ||
| Biofilm and nanowire production leads to increased current in Geobacter sulfurreducens fuel cells | Q39107317 | ||
| The molecular density of states in bacterial nanowires | Q39122964 | ||
| Quantum mechanical tunnelling in biological systems | Q40306374 | ||
| Alignment of the c-type cytochrome OmcS along pili of Geobacter sulfurreducens | Q41517697 | ||
| P921 | main subject | nanowire | Q631739 |
| P304 | page(s) | 43-62; discussion 103-14 | |
| P577 | publication date | 2012-01-01 | |
| P1433 | published in | Faraday Discussions | Q385884 |
| P1476 | title | Physical constraints on charge transport through bacterial nanowires | |
| P478 | volume | 155 |
| Q90068944 | A highly conductive fibre network enables centimetre-scale electron transport in multicellular cable bacteria |
| Q38061981 | A long way to the electrode: how do Geobacter cells transport their electrons? |
| Q64236177 | Addition of Riboflavin-Coupled Magnetic Beads Increases Current Production in Bioelectrochemical Systems via the Increased Formation of Anode-Biofilms |
| Q64448209 | Assessing Possible Mechanisms of Micrometer Scale Electron Transfer in Heme Free Geobacter Sulfurreducens Pili |
| Q56760600 | Biophotovoltaics: oxygenic photosynthetic organisms in the world of bioelectrochemical systems |
| Q28069190 | Cation-limited kinetic model for microbial extracellular electron transport via an outer membrane cytochrome C complex |
| Q35098698 | Charge transfer in dynamical biosystems, or the treachery of (static) images |
| Q36055514 | Defusing redox bombs? |
| Q57188040 | Direct evidence for heme-assisted solid-state electronic conduction in multi-heme -type cytochromes |
| Q64068607 | Electrical energy storage with engineered biological systems |
| Q34565104 | Electrochemically active biofilms: facts and fiction. A review |
| Q47823153 | Electron Hopping Across Hemin-Doped Serum Albumin Mats on Centimeter-Length Scales. |
| Q37495092 | Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials |
| Q51660483 | Electron transfer in peptides: on the formation of silver nanoparticles. |
| Q38684961 | Extracellular polymeric substances are transient media for microbial extracellular electron transfer. |
| Q36062694 | Hardwiring microbes via direct interspecies electron transfer: mechanisms and applications |
| Q64448623 | Harnessing the power of microbial nanowires |
| Q42319261 | High Electronic Conductance through Double-Helix DNA Molecules with Fullerene Anchoring Groups |
| Q47652650 | Impedance spectroscopy of single bacterial nanofilament reveals water-mediated charge transfer |
| Q30791291 | Innovative statistical interpretation of Shewanella oneidensis microbial fuel cells data |
| Q41446981 | Long-distance electron transfer by G. sulfurreducens biofilms results in accumulation of reduced c-type cytochromes. |
| Q46890357 | Long-range charge transport in single G-quadruplex DNA molecules. |
| Q36280012 | Long-range electron transport in Geobacter sulfurreducens biofilms is redox gradient-driven |
| Q37701849 | Long-range electron tunneling |
| Q42632075 | Mean First-Passage Times in Biology |
| Q38407617 | Membrane-intercalating conjugated oligoelectrolytes: impact on bioelectrochemical systems |
| Q51562352 | Microbial nanowires: a new paradigm for biological electron transfer and bioelectronics. |
| Q41004205 | Molecular dissection of bacterial nanowires |
| Q41825632 | Molecular machines and devices |
| Q39515316 | Molecular structure and free energy landscape for electron transport in the decahaem cytochrome MtrF. |
| Q34775341 | Multi-haem cytochromes in Shewanella oneidensis MR-1: structures, functions and opportunities |
| Q46461761 | Multistep hopping and extracellular charge transfer in microbial redox chains. |
| Q88093641 | Observation of Giant Conductance Fluctuations in a Protein |
| Q56503126 | On Electron Transport through Geobacter Biofilms |
| Q41551999 | Proton Transport in the Outer-Membrane Flavocytochrome Complex Limits the Rate of Extracellular Electron Transport |
| Q36782196 | Rapid electron exchange between surface-exposed bacterial cytochromes and Fe(III) minerals. |
| Q38075507 | Review: Probing protein electron transfer mechanisms from the molecular to the cellular length scales |
| Q38266689 | Seeing is believing: novel imaging techniques help clarify microbial nanowire structure and function |
| Q34144770 | Shewanella oneidensis MR-1 nanowires are outer membrane and periplasmic extensions of the extracellular electron transport components |
| Q57164795 | Spatially resolved confocal resonant Raman microscopic analysis of anode-grown Geobacter sulfurreducens biofilms |
| Q57436214 | The Confluence of Heavy Metal Biooxidation and Heavy Metal Resistance: Implications for Bioleaching by Extreme Thermoacidophiles |
| Q46467332 | The Roles of Biofilm Conductivity and Donor Substrate Kinetics in a Mixed-Culture Biofilm Anode |
| Q46125697 | The conjugated oligoelectrolyte DSSN+ enables exceptional coulombic efficiency via direct electron transfer for anode-respiring Shewanella oneidensis MR-1-a mechanistic study. |
| Q84190349 | The diversity of techniques to study electrochemically active biofilms highlights the need for standardization |
| Q36724831 | Thermally activated charge transport in microbial protein nanowires |
| Q51627848 | Thermally activated long range electron transport in living biofilms. |
| Q52725619 | Ultrastructure of Shewanella oneidensis MR-1 nanowires revealed by electron cryotomography. |
| Q41022899 | e-Biologics: Fabrication of Sustainable Electronics with "Green" Biological Materials |
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