Polymer electrolyte membrane (PEM) is one of key elements to determine both electrochemical performances and lifetimes of fuel cell electric vehicles (FCEVs). PEM is exposed to a variety of dynamic stimuli (e.g., temperature, humidity, pressure, fuel gases and so on) under their operation conditions and meets unavoidable mechanical damages derived from unequal pressure difference between anode and cathode feed gases. Even though there have been approaches to evaluate the mechanical strength of PEM materials, most of the trials could provide static information on their mechanical strength. In this study, a pressure-loaded blister hybrid system connected with gas chromatography was developed to disclose the efficacy of the system as an evaluation tool of dynamic PEM strength under realistic FCEV operation conditions.

A key element of environmentally friendly electric vehicles (EVs) based on polymer electrolyte fuel cells (PEFCs) and lithium ion batteries (LIBs) is an ion-selective membrane, which can transport specific ions such as proton and lithium ions, and provide mechanical and chemical resistances. The state-of-the art membranes for PEFCs and LIBs are perfluorinated sulfonic acid ionomer reinforced membranes and ceramic-coated polyolefin separators, respectively. In spite of the improvement of membranes characteristics, additional membrane modifications are still needed to improve electrochemical cell performances and to extend their lifetime. In this presentation, several plausible approaches to improve membrane characteristics are introduced.