Intrinsic electrical properties of cable bacteria reveal an Arrhenius temperature dependence

Filamentous cable bacteria exhibit long-range electron transport over centimetre-scale distances, which takes place in a parallel fibre structure with high electrical conductivity. Still, the underlying electron transport mechanism remains undisclosed. Here we determine the intrinsic electrical prop...

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Bibliographic Details
Published in:Scientific reports 2020-11, Vol.10 (1), p.19798-19798, Article 19798
Main Authors: Bonné, Robin, Hou, Ji-Ling, Hustings, Jeroen, Wouters, Koen, Meert, Mathijs, Hidalgo-Martinez, Silvia, Cornelissen, Rob, Morini, Filippo, Thijs, Sofie, Vangronsveld, Jaco, Valcke, Roland, Cleuren, Bart, Meysman, Filip J. R., Manca, Jean V.
Format: Article
Language:English
Subjects:
631/326
639/766
Bacteria
Electric Conductivity
Electrical conductivity
Electrical properties
Electrochemistry
Electron transport
Electron Transport - physiology
Fibers
Filaments
Humanities and Social Sciences
multidisciplinary
Science
Science (multidisciplinary)
Semiconductors
Spectroscopy
Temperature
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Summary:Filamentous cable bacteria exhibit long-range electron transport over centimetre-scale distances, which takes place in a parallel fibre structure with high electrical conductivity. Still, the underlying electron transport mechanism remains undisclosed. Here we determine the intrinsic electrical properties of the conductive fibres in cable bacteria from a material science perspective. Impedance spectroscopy provides an equivalent electrical circuit model, which demonstrates that dry cable bacteria filaments function as resistive biological wires. Temperature-dependent electrical characterization reveals that the conductivity can be described with an Arrhenius-type relation over a broad temperature range (− 195 °C to + 50 °C), demonstrating that charge transport is thermally activated with a low activation energy of 40–50 meV. Furthermore, when cable bacterium filaments are utilized as the channel in a field-effect transistor, they show n-type transport suggesting that electrons are the charge carriers. Electron mobility values are ~ 0.1 cm 2 /Vs at room temperature and display a similar Arrhenius temperature dependence as conductivity. Overall, our results demonstrate that the intrinsic electrical properties of the conductive fibres in cable bacteria are comparable to synthetic organic semiconductor materials, and so they offer promising perspectives for both fundamental studies of biological electron transport as well as applications in microbial electrochemical technologies and bioelectronics.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-020-76671-5