posted on 2018-09-24, 00:00authored byHenrike Schmies, Elisabeth Hornberger, Björn Anke, Tilman Jurzinsky, Hong Nhan Nong, Fabio Dionigi, Stefanie Kühl, Jakub Drnec, Martin Lerch, Carsten Cremers, Peter Strasser
Nitrogen-enriched
porous carbons have been discussed as supports
for Pt nanoparticle catalysts deployed at cathode layers of polymer
electrolyte membrane fuel cells (PEMFC). Here, we present an analysis
of the chemical process of carbon surface modification using ammonolysis
of preoxidized carbon blacks, and correlate their chemical structure
with their catalytic activity and stability using in situ analytical
techniques. Upon ammonolysis, the support materials were characterized
with respect to their elemental composition, the physical surface
area, and the surface zeta potential. The nature of the introduced
N-functionalities was assessed by X-ray photoelectron spectroscopy.
At lower ammonolysis temperatures, pyrrolic-N were invariably the
most abundant surface species while at elevated treatment temperatures
pyridinic-N prevailed. The corrosion stability under electrochemical
conditions was assessed by in situ high-temperature differential electrochemical
mass spectroscopy in a single gas diffusion layer electrode; this
test revealed exceptional improvements in corrosion resistance for
a specific type of nitrogen modification. Finally, Pt nanoparticles
were deposited on the modified supports. In situ X-ray scattering
techniques (X-ray diffraction and small-angle X-ray scattering) revealed
the time evolution of the active Pt phase during accelerated electrochemical
stress tests in electrode potential ranges where the catalytic oxygen
reduction reaction proceeds. Data suggest that abundance of pyrrolic
nitrogen moieties lower carbon corrosion and lead to superior catalyst
stability compared to state-of-the-art Pt catalysts. Our study suggests
with specific materials science strategies how chemically tailored
carbon supports improve the performance of electrode layers in PEMFC
devices.