4.6 Article

Efficient Hydrogen Delivery for Microbial Electrosynthesis via 3D-Printed Cathodes

Journal

FRONTIERS IN MICROBIOLOGY
Volume 12, Issue -, Pages -

Publisher

FRONTIERS MEDIA SA
DOI: 10.3389/fmicb.2021.696473

Keywords

microbial electrosynthesis; gas fermentation; bioelectrochemical system; hydrogen mass transfer; current density; 3D-printing; additive manufacturing (3D printing)

Categories

Funding

  1. U.S. Department of Energy through the Bioenergy Technologies Office (BETO)
  2. Lawrence Livermore National Laboratory, Stanford University [TC02293]
  3. Southern California Gas Company [TC02293]
  4. U.S. Department of Energy [DE-AC52-07NA27344]

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This study demonstrates the use of complex 3D-printed custom electrodes to fine tune H-2 delivery during microbial electrosynthesis. The results show that larger surface area cathodes enable higher methane production and minimize escape of H-2, thus facilitating efficient electromethanogenesis.
The efficient delivery of electrochemically in situ produced H-2 can be a key advantage of microbial electrosynthesis over traditional gas fermentation. However, the technical details of how to supply large amounts of electric current per volume in a biocompatible manner remain unresolved. Here, we explored for the first time the flexibility of complex 3D-printed custom electrodes to fine tune H-2 delivery during microbial electrosynthesis. Using a model system for H-2-mediated electromethanogenesis comprised of 3D fabricated carbon aerogel cathodes plated with nickel-molybdenum and Methanococcus maripaludis, we showed that novel 3D-printed cathodes facilitated sustained and efficient electromethanogenesis from electricity and CO2 at an unprecedented volumetric production rate of 2.2 L-CH4 /L-catholyte/day and at a coulombic efficiency of 99%. Importantly, our experiments revealed that the efficiency of this process strongly depends on the current density. At identical total current supplied, larger surface area cathodes enabled higher methane production and minimized escape of H-2. Specifically, low current density (< 1 mA/cm(2)) enabled by high surface area cathodes was found to be critical for fast start-up times of the microbial culture, stable steady state performance, and high coulombic efficiencies. Our data demonstrate that 3D-printing of electrodes presents a promising design tool to mitigate effects of bubble formation and local pH gradients within the boundary layer and, thus, resolve key critical limitations for in situ electron delivery in microbial electrosynthesis.

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