Johannes Erben scite author profile

We study the current production of Shewanella oneidensis MR-1 with electrospun carbon fiber anode materials and analyze the effect of the anode morphology on the micro-, meso- and macroscale. The materials feature fiber diameters in the range between 108 nm and 623 nm, resulting in distinct macropore sizes and surface roughness factors. A maximum current density of (255 ± 71) μA cm-2 was obtained with 286 nm fiber diameter material. Additionally, micro- and mesoporosity were introduced by CO2 and steam activation which did not improve the current production significantly. The current production is directly linked to the biofilm dry mass under anaerobic and micro-aerobic conditions. Our findings suggest that either the surface area or the pore size related to the fiber diameter determines the attractiveness of the anodes as habitat and therefore biofilm formation and current production. Reanalysis of previous works supports these findings.

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Revisiting methods to characterize bioelectrochemical systems: The influence of uncompensated resistance (iR-drop), double layer capacitance, and junction potential

Madjarov

Popat

Erben

et al. 2017

Journal of Power Sources

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Johannes Erben

Systematic screening of carbon-based anode materials for microbial fuel cells with Shewanella oneidensis MR-1

Characterization of microbial current production as a function of microbe–electrode-interaction

Simple fabrication of 12 μm thin nanocomposite fuel cell membranes by direct electrospinning and printing

High current production ofShewanella oneidensiswith electrospun carbon nanofiber anodes is directly linked to biofilm formation

Revisiting methods to characterize bioelectrochemical systems: The influence of uncompensated resistance (iR-drop), double layer capacitance, and junction potential

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