Proton conductivity and fuel cell property of composite electrolyte consisting of Cs-substituted heteropoly acids and sulfonated poly(ether–ether ketone)

Abstract

Inorganic–organic composite electrolytes were fabricated from partially Cs +-substituted heteropoly acids (Cs-HPAs) and sulfonated poly(ether–ether ketone) (SPEEK) for application in fuel cells. Heteropoly acids, such as phosphotungstic acid (H 3PW 12O 40:WPA), and silicotungstic acid (H 4SiW 12O 40:WSiA), were mechanochemically treated with cesium hydrogen sulfate (CsHSO 4) to obtain the form of Cs-HPAs. SPEEK was prepared from PEEK by sulfonation using concentrated sulfuric acid. Water durability and surface structure of HPAs were modified by introducing Cs + into HPAs. Flexible and hot water stable composite electrolytes were obtained, and their electrochemical properties were markedly improved with the addition of Cs-HPAs into the SPEEK matrix. Maximum power densities of 245 and 247 mW cm −2 were obtained for 50WPA·50CsHSO 4 and 50WSiA·50CsHSO 4 in SPEEK (1/5 by weight) composite electrolytes, respectively, from single cell tests at 80 °C and 80 RH%. These results suggest that a three-dimensional proton-conductive path was formed among homogeneously distributed Cs-HPAs particles in the SPEEK matrix. The Cs-HPAs incorporated into the SPEEK matrix increased the number of protonate sites in the electrolyte. These observations imply that the mechanochemically synthesized Cs-HPAs, which consist of hydrogen bondings between Cs-HPAs and –HSO 4 −, dissociated from CsHSO 4, are promising materials as inorganic fillers in inorganic–organic composite.