4.5 Article

Atmospheric plasma deposition of conductive and corrosion-resistant composite coatings for proton exchange membrane fuel cell bipolar plates

Journal

PLASMA PROCESSES AND POLYMERS
Volume 20, Issue 8, Pages -

Publisher

WILEY-V C H VERLAG GMBH
DOI: 10.1002/ppap.202300056

Keywords

atmospheric plasma deposition; atmospheric pressure dielectric barrier discharge; bipolar plates; composite coatings; proton exchange membrane fuel cells

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A scalable and solvent-free atmospheric plasma deposition process is used to synthesize conductive and corrosion-protective composite coatings suitable for proton exchange membrane fuel cell (PEMFC) bipolar plate preparation. The use of small three-dimensional carbon black nanoparticles and large two-dimensional natural graphite flakes as conductive fillers is investigated. It is found that the conventional dual-sized conductive fillers strategy is not applicable for the proposed atmospheric plasma deposition process. Only the composite coatings prepared from large two-dimensional natural graphite flakes show a significant decrease in corrosion current and interfacial contact resistance in simulated PEMFC conditions.
The straightforward synthesis and application of conductive and corrosion-protective composite coatings suitable for the preparation of bipolar plates of proton exchange membrane fuel cells (PEMFCs) are achieved by a scalable and solvent-free atmospheric plasma deposition process. Small three-dimensional (3D) carbon black nanoparticles and large two-dimensional (2D) natural graphite flakes are investigated independently and together as conductive fillers. It is demonstrated that the dual-sized conductive fillers strategy traditionally used for the preparation of composite bipolar plates is not transposable for the proposed atmospheric plasma deposition process. Only the composite coatings prepared from large 2D natural graphite flakes enable a significant decrease of the corrosion current in simulated proton exchange membrane fuel cell conditions while ensuring interfacial contact resistance in the order of several tens of m omega center dot cm(2).

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