Published in
Elsevier, Applied Surface Science, (442), p. 501-506, 2018
DOI: 10.1016/j.apsusc.2018.02.171
Elsevier, Applied Surface Science, (432), p. 7-14, 2018
DOI: 10.1016/j.apsusc.2017.06.024
Elsevier, Applied Surface Science, (419), p. 235-240, 2017
DOI: 10.1016/j.apsusc.2017.05.029
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Tools
In vitro characterization of two different atmospheric plasma jet chemical functionalizations of titanium surfaces
,
Ugo de Grazia,
F. Mussano,
David Scarpellini,
Claudio Somaschini,
E. Verga Falzacappa ,
Matteo Tommasini ,
Marco Salvalaglio,
P. Scopece,
T. Genova,
Anna Marzegalli,
Sebastiano Trusso,
L. Munaron ,
Francesco Montalenti,
Stefano Sanguinetti
and other authors.
Full text: Download
Abstract
In electrodes of low temperature fuel cells like polymer electrolyte membrane fuel cells (PEFC) or alkaline fuel cells (AFC) the reactants and the water must be transported. For this purpose the pore system in the electrodes needs a hydrophilic character for the transport of the water and a hydrophobic character for the transport of the gases. The degree of the hydrophobicity determines whether the pore system will be flooded by the reaction water. In the case of PEFC, this is also determined by the degree of the required humidification of the reaction gases. In AFC hydrophobicity determines the extension of the three-phase reaction zone. Caused by the strong influence of hydrophobicity on the transport processes, the electrochemical performance and the optimized operation conditions are also affected by hydrophobicity. Typically polytetrafluoro-ethylene (PTFE) is used to make the electrodes hydrophobic, because PTFE has a high chemical stability. Hydrophobicity depends on the concentration of PTFE on the electrode surface. The PTFE concentration, which is related to the hydrophobic character, can be determined by XPS. The changes in the PTFE content and structure of the electrode of a PEFC was investigated by cyclic voltammetry and XPS and correlated with the performance of the cell in long-term operation. With both methods an initial significant increase in free and electrochemically active surface platinum area is observed. This activation is associated with a degradation of the PTFE in the electrode which is responsible for the hydrophobic properties of the electrode. With further operation the performance of the cell decreases because the water management becomes more critical. Generally, it is shown that XPS can be used for the investigation of the hydrophobicity of electrodes prepared by various manufacturing techniques as well as of changes in their hydrophobicity induced by the electrochemical operation.