Sulfonated fluorinated multi-block copolymer hybrid containing sulfonated（poly ether ether ketone） and graphene oxide： A ternary hybrid membrane architecture for electrolyte applications in proton exchange membrane fuel cells

摘要

cqvip:A ternary hybrid membrane architecture consisting of sulfonated fluorinated multi-block copolymer(SFMC), sulfonated(poly ether ether ketone)(SPEEK) and 1 or 5 wt% graphene oxide(GO) was fabricated through a facile solution casting approach. The simple, but effective monomer sulfonation was performed for SFMC to create compact and rigid hydrophobic backbone structures, while conventional random sulfonation was carried-out for SPEEK. Hydrophilic-hydrophobic-hydrophilic structure of SFMC enhances the compatibility with SPEEK and GO and allows for an unprecedented approach to alter mechanical strength and proton conductivity of ternary hybrid membrane, as verified from universal test machine(UTM) curves and alternating current(AC) impedance plots. The impact of GO integration on the morphology and roughness of hybrid membrane was scrutinized using field emission scanning electron microscope(FE-SEM) and atomic force microscope(AFM). Ternary hybrid showed uniform intercalation of GO nanosheets throughout the entire surface of membrane with an increased surface roughness of 8.91 nm. The constructed ternary hybrid membrane revealed excellent water absorption, ion exchange capacity and gas barrier properties, while retaining reasonable dimensional stability. The well-optimized ternary hybrid membrane containing 5 wt% GO revealed a maximum proton conductivity of 111.9 m S/cm,which is higher by a factor of two-fold with respect to that of bare SFMC membrane. The maximum PEMFC power density of 528.07 m W/cm2 was yielded by ternary hybrid membrane at a load current density of 1321.1 m A/cm2 when operating the cell at 70 °C under 100% relative humidity(RH). In comparison, a maximum power density of only 182.06 m W/cm2 was exhibited by the bare SFMC membrane at a load current density of 455.56 m A/cm2 under same operating conditions.