Highly hydroxide-conductive anion exchange membrane with PIL@MOF-assisted ion nanochannels

A highly hydroxide-conducting anion exchange membrane with well-organized multi ion channels were fabricated via incorporating poly ionic liquids modified MIL101 (PIL@MIL101) into imidazolated poly (2,6-dimethyl-1,4-phenylene oxide) (ImPPO). 1-Vinyl-3-ethylimidzolium bromine was first immobilized in MIL101 cages via supercritical fluid impregnation method. Afterwards, the rigid-assisted ion nanochannels were constructed by in-situ polymerization of ionic liquids within the long-range ordered pores of MIL101. Meanwhile, PPO was functionalized by 1-ethyl-2-methyimidzolium to prepare combshaped ImPPO with enhanced microphase separation structure. Then the PIL@MIL101 was combined with ImPPO to fabricate hybrid anion exchange membrane with well-organized multiple ion channels. The OH conductivity of the hybrid membrane significantly reached 138 mS/cm at 80 degrees C (176% higher than that of pristine membrane). Furthermore, the stability and mechanical properties of the hybrid membranes were remarkably enhanced. The excellent performances render the hybrid membrane a good candidate for the application in anion exchange membrane fuel cells. (C) 2020 The Korean Society of Industrial and Engineering Chemistry. Published by Elsevier B.V. All rights reserved.

Automated summary

A high hydroxide-conducting anion exchange membrane with well-organized multi ion channels was fabricated by incorporating poly ionic liquids modified MIL101 (PIL@MIL101) into ImPPO. The hybrid membrane showed significantly improved OH conductivity, enhanced stability, and mechanical properties, making it a promising candidate for anion exchange membrane fuel cells.