A series of poly(meta/para-terphenylene-methyl piperidinium)-based anion exchange membranes devoid of benzylic sites or aryl ether bonds, that are vulnerable to degradation by hydroxide ions, are synthesized and investigated for their application as novel anion exchange membranes. The copolymers are composed of both linear para-terphenyl units and kink-structured meta-terphenyl units. The meta-connectivity in terphenyl units permits the polymer backbones to fold back, maximizing the interactions among the hydrocarbon polymer chains and enhancing the peripheral formation of ion aggregates, due to the free volume generated by the kink structure. The effects of the copolymer composition between para-terphenyl and meta-terphenyl on the morphology and the electrochemical and physicochemical properties of the corresponding polymer membranes are investigated.
We prepared Nafion
composite membranes by impregnating Nafion-212
with polydopamine, poly(sulfonated dopamine), and poly(dopamine-
co
-sulfonated dopamine) using the swelling–filling
method to generate nanopores in the Nafion framework that were filled
with these polymers. Compared to the pristine Nafion-212 membrane,
these composite membranes showed improved thermal and mechanical stabilities
due to the strong interactions between the catecholamine of the polydopamine
derivatives and the Nafion matrix. For the composite membrane filled
with poly(sulfonated dopamine) (N-PSDA), further interactions were
induced between the Nafion and the sulfonic acid side chain, resulting
in enhanced water uptake and ion conductivity. In addition, filling
the nanopores in the Nafion matrix with polymer fillers containing
aromatic hydrocarbon-based dopamine units led to an increase in the
degree of crystallinity and resulted in a significant decrease in
the hydrogen permeability of the composite membranes compared to Nafion-212.
Hydrogen crossovers 26.8% lower than Nafion-212 at 95% relative humidity
(RH) (fuel cell operating conditions) and 27.3% lower at 100% RH (water
electrolysis operating conditions) were obtained. When applied to
proton exchange membrane-based fuel cells, N-PSDA exhibited a peak
power density of 966 mW cm
–2
, whereas N-PSDA showed
a current density of 4785 mA cm
–2
, which is 12.4%
higher than Nafion-212 at 2.0 V and 80 °C.
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