Scheiba, Frieder (2009)
ELECTRODE STRUCTURES OF POLYMER ELECTROLYTE FUEL CELLS (PEFC) - An electron microscopy approach to the characterization of the electrode structure of polymer electrolyte fuel cells.
Technische Universität Darmstadt
Dissertation, Erstveröffentlichung

Kurzbeschreibung (Abstract)

Polymer electrolyte fuel cells (PEFC) have a complex electrode structure, which usually consists of a catalyst, a catalyst support, a polymer electrolyte and pores. The materials used are largely amorphous, have a strong defective structure or have particle diameter of only a few nanometers. In the electrode the materials form highly disordered aggregated structures. Both aspects complicate a systematic structural analysis significantly. However, thorough knowledge of the electrode structure, is needed for systematic advancement of fuel cell technology and to obtain a better understanding of mass and charge carrier transport processes in the electrode. Because of the complex structure of the electrode, an approach based on the examination of electrode thin-sections by electron microscopy was chosen in this work to depicting the electrode structure experimentally. The present work presents these studies of the electrode structure. Some fundamental issues as the influence of the polymer electrolyte concentration and the polarity of the solvent used in the electrode manufacturing process were addressed. During the analysis particular attention was payed to the distribution and structure of the polymer electrolyte. A major problem to the investigations, were the low contrast between the polymer electrolyte, the catalyst support material and the embedding resin. Therefore, different techniques were investigated in terms of their ability to improve the contrast. In this context, a computer-assisted acquisition procedure for energy filtered transmission electron microscopy (EF-TEM) was developed. The acquisition procedure permits a significant extension of the imageable sample. At the same time, it was possible to substantially reduce beam damage of the specimen and to minimize drift of the sample considerably. This allowed unambiguous identification of the polymer electrolyte in the electrode. It could further be shown, that the polymer electrolyte not only coats the catalyst and catalyst support, but that it forms a complex structure consisting of fiber and film like structures in the pores of the electrode. In addition, the EF-TEM result delivered a strong indication for the infiltration of catalyst agglomerates by the polymer electrolyte. Furthermore, a new concept for the investigation of multi-component structures, consisting of the membrane, electrodes and gas diffusion layers (GDL) was developed. Thus it was possible to provide evidence for the intrusion of individual carbon fibers from the GDL into the electrode. In addition the influence of GDL structure on delamination of the electrode could be demonstrated. Another part of the work deals with the characterization of a novel platinum catalyst deposited on hydrous ruthenium oxide coated carbon nanotubes (CNT), which was developed in close cooperation with a Chinese partner at Tsinghua University (Beijing).

Frage zum Eintrag

Redaktionelle Details anzeigen