Influence of {FEP} nanoparticles in catalyst layer on water management and performance of {PEM} fuel cell with high Pt loading
By Avcioglu, Gokce S.; Ficicilar, Berker; Eroglu, Inci
Published in International Journal of Hydrogen Energy
NULL
2017
Abstract
Abstract In this study, fluorinated ethylene propylene (FEP) nanoparticles were added to catalyst layer (CL) to facilitate excess water removal from the triple phase boundary in high Pt loading (1.2 mg/cm2) proton exchange membrane fuel cell (PEMFC) electrodes. The loading of {FEP} in the catalyst ink was varied from zero to 30 weight percentage. High-performance electrodes for anode and cathode were prepared by ultrasonic spray coating technique with a commercial catalyst containing 70 wt. % Pt on carbon. Different membrane electrode assemblies (MEAs) were prepared in order to differentiate the influence of hydrophobic nanoparticles on water transport and cell performance. In the first configuration (MEA1), {FEP} nanoparticles were added to both anode and cathode catalyst layers (cCLs). In the second configuration (MEA2), {FEP} nanoparticles were added only to cCL. {PEM} fuel cell tests were carried out at both H2/O2 and H2/Air gas-feeding modes. Impedance spectroscopy results have revealed the influence of {FEP} nanoparticles on reaction kinetics and mass transport limitations. The addition of {FEP} nanoparticles decreased Pt utilization due to the isolation of Pt particles, therefore, cell performance decreased. Electrochemical impedance spectroscopy results have shown increasing back diffusion rate of water, and diminishing flooding at cathode {GDL} at high airflow rate. {FEP} nanoparticles in the cCLs of 10FEP_C, 5FEP_C at H2/O2 feeding mode and in the {CLs} of 5FEP_AC, 5FEP_C at H2/Air feeding mode provide meso-macro hydrophobic channeling, which mitigates flooding compared to conventional catalyst layers. For anode and cathode catalyst layer including 30 wt. % {FEP} nanoparticles (30FEP_AC), capillary pressure increased due to high hydrophobicity, accordingly, liquid water concentration at anode catalyst layer/membrane interface decreased and this caused membrane dehydration.
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