Modification of Hydrophobic Diacid Units for Enhanced Poly(crown ether) Anion-Exchange Membrane Performance

Abstract: Ideal anion-exchange membranes (AEMs) for anion-exchange membrane fuel cells (AEMFCs) must possess high OH − conductivity, excellent alkaline resistance, good thermal stability, and improved dimensional stability. In this study, four types of poly(crown ether) (PCE) cross-linked AEMs containing different aromatic or alicyclic dicarboxylic acids were prepared for AEMFCs. The hydrophilic/hydrophobic polarity discrimination of AEMs can be adjusted by the introduction of various diacids into the polymer backbones.… Show more

“…5 Fuel cells based on conventional quaternary amine aromatic polymers typically exhibit good fuel cell performance, long-term durability, hydroxide conductivity, adequate ion exchange capacity, and stability in alkaline environments. 6 While these characteristics contribute to satisfactory AEMFC performance, they may also result in higher water uptake and less controlled dimensional stability. Consequently, a common approach involves the development and synthesis of quaternary amine aromatic polymers with tailored molecular structures to address these issues in AEMFCs.…”

“…Many polymers have been investigated as alternatives to PFSA in PEMFC fuel cells to provide low cost, high fuel resistance, excellent physicochemical and thermal stability, and outstanding mechanical properties . Fuel cells based on conventional quaternary amine aromatic polymers typically exhibit good fuel cell performance, long-term durability, hydroxide conductivity, adequate ion exchange capacity, and stability in alkaline environments . While these characteristics contribute to satisfactory AEMFC performance, they may also result in higher water uptake and less controlled dimensional stability.…”

Anion Exchange Membrane Based on Cross-Linked Poly(2,6-dimethyl-1,4-phenylene oxide)/Poly(dimethylaminophenyl bisdiphenol) for Fuel Cell Applications

“…5 Fuel cells based on conventional quaternary amine aromatic polymers typically exhibit good fuel cell performance, long-term durability, hydroxide conductivity, adequate ion exchange capacity, and stability in alkaline environments. 6 While these characteristics contribute to satisfactory AEMFC performance, they may also result in higher water uptake and less controlled dimensional stability. Consequently, a common approach involves the development and synthesis of quaternary amine aromatic polymers with tailored molecular structures to address these issues in AEMFCs.…”

“…Many polymers have been investigated as alternatives to PFSA in PEMFC fuel cells to provide low cost, high fuel resistance, excellent physicochemical and thermal stability, and outstanding mechanical properties . Fuel cells based on conventional quaternary amine aromatic polymers typically exhibit good fuel cell performance, long-term durability, hydroxide conductivity, adequate ion exchange capacity, and stability in alkaline environments . While these characteristics contribute to satisfactory AEMFC performance, they may also result in higher water uptake and less controlled dimensional stability.…”

Anion Exchange Membrane Based on Cross-Linked Poly(2,6-dimethyl-1,4-phenylene oxide)/Poly(dimethylaminophenyl bisdiphenol) for Fuel Cell Applications

Effects of side chain length on the performance of poly(aryl-alkylene) anion exchange membranes for fuel cells

Synthesis and characterization of ionic liquid incorporated quaternized poly(2,6-dimethyl-1,4-phenylene oxide) and NiO/IrO₂ electrocatalyst for anion exchange membrane fuel cell applications