Fe-N-C materials
are promising oxygen reduction reaction (ORR)
catalysts for replacing expensive platinum-based catalysts (Pt/C)
in proton exchange membrane fuel cells. However, they still show low
volumetric activity and stability compared to Pt/C catalysts, with
carbon corrosion being one of the main factors for the loss of active
Fe-N
x
sites. Within this study, phosphoric
acid-activated rye straw and coconut shells are revealed as a promising
matrix for Fe-N
x
sites with advanced stability
against electrochemical carbon corrosion (5000 cycles, 1.0–1.5
VRHE, and 0.1 M HClO4) compared to a common
Fe-N-C catalyst based on carbon black. Electrochemical characterization
of the two biomass-based catalysts (Fe-N-CBio) shows on
the one hand 50% higher stability in terms of mass activity as well
as comparable activity and active site density but on the other hand
a lower selectivity toward the four-electron ORR than the common Fe-N-C
catalyst. Nitrite stripping experiments in acetate buffer as an electrolyte
display a 1.5-fold stronger effect of carboxylic acid adsorption than
on a common Fe-N-C catalyst, revealing differences to the electronic
structure of the Fe-N-CBio catalyst. This difference is
mainly attributed to the presence of phosphor species and higher amounts
of nitrogen functionalities in the Fe-N-CBio catalysts.
The presence of P is assumed to stabilize the carbon against carbon
corrosion by inhibiting electron withdrawal from the C. This study
points out the impact factors on Fe-N-C stability and further shows
the promising application of activated biomasses in more stable and
sustainable Fe-N-C catalysts for ORR.
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