Abstract
The composite structure, good porosity, and electrochemical behavior of proton exchange membranes (PEMs) are important characteristics, which can improve the performance of polymer electrolyte fuel cells (PEFCs). In this study, we designed and synthesized an XY block copolymer via a polycondensation reaction that contains sulfonated poly(ether ether ketone) (SPEEK) (X) as a hydrophilic unit and a fluorinated oligomer (Y) as a hydrophobic unit. The prepared XY block copolymer is composed of Fe&sub3;O&sub4; nanoparticles to create composite architecture, which was subsequently treated with a 1 M H&sub2;SO&sub4; solution at 70 °C for 1 h to eliminate Fe&sub3;O&sub4; and generate a pores structure in the membrane. The morphological, physiochemical, thermomechanical, and electrochemical properties of bare XY, XY/Fe&sub3;O&sub4;-9 and XY(porous)-9 membranes were measured and compared in detail. Compared with XY/Fe&sub3;O&sub4;-9 composite, the proton conductivity of XY(porous)-9 membrane was remarkably enhanced as a result of the existence of pores as nano-conducting channels. Similarly, the XY(porous)-9 membrane exhibited enhanced water retention and ion exchange capacity among the prepared membranes. However, the PEFC power density of XY(porous)-9 membrane was still lower than that of XY/Fe&sub3;O&sub4;-9 membrane at 60 °C and 60% relative humidity. Also, the durability of XY(porous)-9 membrane is found to be lower compared with pristine XY and XY/Fe&sub3;O&sub4;-9 membranes as a result of the hydrogen crossover through the pores of the membrane.