Advanced proton exchange membrane prepared from N-heterocyclic poly (aryl ether ketone)s with pendant benzenesulfonic moieties and performing enhanced radical tolerance and fuel cell properties

The application of sulfonated poly(aryl ether)s proton exchange membranes in fuel cells is hampered by the inadequate oxidation stability and the trade-off effect between proton-conducting performance and physico-chemical stability. So the sulfonated N-heterocyclic poly(aryl ether ketone)s (SPBPEK-Ps) membranes possessing fine proton-conducting behavior and radical tolerance are manufactured by the elaborate design of molecular backbones. The hydrophilic units containing proton-conducting groups in pendant moieties in SPBPEK-Ps contribute to constructing developed proton-conducting channels, in which the multiple interactions between sulfonic groups and N-heterocycles further promote proton conduction with the conductivity of up to 125 mS cm-1. The fuel cells loading SPBPEK-Ps membranes perform a power density of up to 1210 mW cm-2 with hypo-sensitivity to temperature and oxidized gas. A couple of steric hindrances from pendant proton-conducting groups and the diminished affinity of radicals for molecular chains resulting from the introduction of N-het-erocyclic structure enhance the oxidation stability of SPBPEK-Ps membranes, and the break time of the mem-branes at 80 degrees C ranges in 2.5-7.8 h. The combination of the pendant proton-conducting groups and N-heterocycles with the electron-withdrawing effect would contribute to improving proton-conducting perfor-mance and oxidation stability and attenuating the trade-off effect between them.