Synthesis and properties of alkaline stable pyridinium containing anion exchange membranes

Vöge, Andrea; Deimede, Valadoula; Kallitsis, Joannis K.

doi:10.1039/c4ra07616h

Cited by 43 publications

(22 citation statements)

References 35 publications

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“…To solve the problems faced by AEMs with quaternary ammonium groups, such as facile degradation and excessive swelling, there is a resurgence of exploring AEMs with functional groups different from quaternary ammonium. The ever reported functional groups different from quaternary ammonium for AEMs are shown in Figure 12, including imidazolium 241–261, substituted imidazolium 262–274, benzimidazolium 275, 276, 1,2,3‐triazoles 277, TMP and DMP 278, QPOH 279–283, guanidinium 284–294, morpholinium 292, 293, DABCO 294–302, tetrakis(dialkylamino)phosphonium 303, triarylsulfonium 304, methylated melamine 305, pyrrolidinium 306, pyridinium 307, 308, TQA 309, GQA 310 and morpholinium 311.…”

Section: Aems For Aemfcsmentioning

confidence: 99%

Anion‐Exchange Membranes for Fuel Cells: Synthesis Strategies, Properties and Perspectives

et al. 2015

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This review focuses on various synthesis strategies of anion‐exchange membranes (AEMs) for fuel cells, diverse methodologies of AEM‐forming, together with relationship between structures and properties. AEMs are discussed from seven categories, including (1) AEMs derived from Nafion precursors with sulfonyl fluoride groups, which display excellent stability and well‐developed morphologies that similar to Nafion, but has potentially high costs. (2) AEMs prepared by grafting technologies, such as chemical grafting technique, ATRP technique, plasma grafting technique and radiation grafting technique. (3) AEMs based on functionalized commercial polymers, including PVA, SEBS, CPP, PEEK, PES, PEI, PPO, and so on. (4) AEMs prepared by newly‐synthesized polymers, in which the most interesting approach is to synthesize alkaline multi‐block copolymers with enough long hydrophilic/hydrophobic blocks. (5) AEMs containing heterogeneous composition, which mainly prepared by blending and sol‐gel methods, reinforced or pore‐filling AEMs and IPN or s‐IPN. (6) AEMs with functional groups different from quaternary ammonium, which includes the studies of new type of AEMs with highly chemical stability in alkaline solution. (7) Hybrid membranes combining AEM with PEM, in which new configuration results in different performances. At last, conclusions and perspectives for the future researches of AEMs are presented.

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Section: Aems For Aemfcsmentioning

confidence: 99%

Anion‐Exchange Membranes for Fuel Cells: Synthesis Strategies, Properties and Perspectives

et al. 2015

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“…Alternative cationic groups like guanidinium ones have also used in PPO and PES membranes showing remarkably high ionic conductivity. Likewise, pyridinium based AEMs were prepared for alkaline fuel cells in spite of its low alkaline stability. Unlike these groups, imidazolium (Im) was proposed as a good alternative.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and characterization of benzimidazolium-functionalized polysulfones as anion-exchange membranes

Pérez‐Prior

Várez

Levenfeld

2015

J. Polym. Sci. Part A: Polym. Chem.

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Anion‐exchange membranes containing pendant benzimidazolium groups were synthesized from polysulfone by chrolomethylation followed by nucleophilic substitution reaction with 1‐methylbenzimidazole. The structures of the polymers were characterized by 1H‐NMR and FTIR analysis. The resulting membranes showed high thermal stability below 200 °C. The values of water uptake and swelling degree increased with the ion‐exchange capacity of the polymeric membrane. The ionic conductivity was measured by means of impedance spectroscopy in aqueous solution of potassium hydroxide (10−4−10−1 M). The results show not only a clear correlation between the membrane's electrochemical behavior with the electrolyte solution embedded in the membrane, but also with the degree of the polysulfone's chloromethylation.Thus, the ionic conductivity increased more than two orders of magnitude when the degree of chloromethylation increased from 40 to 140%. Benzimidazolium‐functionalized polysulfones exhibited better thermal, mechanical, and electrochemical properties than the widely used polymeric membranes containing quaternary ammonium groups. © 2015 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2015, 53, 2363–2373

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“…[22][23][24] There are some recent reports of alkaline stable AEMs containing pendant side chains or crosslinked pendant side chains, AEMs prepared from block copolymers and AEMs with the cation group imbedded along the linear polymer backbone. [25][26][27][28][29] In the case of AEMs prepared with side chains and from block copolymers, high alkaline stability was obtained and attributed to the phase-separation between the hydrophilic domains and hydrophobic domains, where the fixed cation groups in the hydrophilic domains remained well solvated. 25,26,29 Increasing the solvation of the cation group in the presence of the hydroxide ion enhances the stability of the cation.…”

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confidence: 99%

“…30 Cation groups imbedded along the linear polymer backbones can be sterically hindered, mitigating hydroxide ion attack at these sites. 27,28 Poly(arylene ether) backbones are desirable for AEMs because of their high oxidative stability and their simple synthesis from commercially available polymers. 31 A major drawback to using poly(arylene ether) backbones (e.g., poly(arylene ether) sulfone (PSF) and poly(2,6-dimethyl 1,4-phenyle oxide (PPO)) for AEMs is that the AEMs become brittle in alkaline solutions over time.…”

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confidence: 99%

Mechanically Stable Poly(arylene ether) Anion Exchange Membranes Prepared from Commercially Available Polymers for Alkaline Electrochemical Devices

Arges

Wang

Jung

et al. 2015

J. Electrochem. Soc.

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The alkaline stability of poly(arylene ether) backbones in anion exchange polymer electrolyte membranes (AEMs) derivatized with quaternary benzyl N, N-dimethylhexylammmonium (DMH + ) and trimethylammonium (TMA + ) cation groups were investigated in poly(2,6-dimethyl 1,4-phenylene) oxide (PPO) and Udel polysulfone (PSF) polymers. Previous studies have demonstrated that quaternary ammonium and phosphonium groups trigger backbone degradation in commercially available poly(arylene ether)-based AEMs, despite the base polymers being resilient to alkaline solutions. Herein, we demonstrate that the electron withdrawing or donating character in the poly(arylene ether) backbone ultimately decides whether or not the prepared AEMs will become brittle in alkaline media due to cation triggered backbone degradation. Mitigation of cation triggered backbone degradation was only achieved when electron withdrawing substituents (not including the cation), such as sulfone or bromine groups, were eliminated from the polymer backbone (or, alternately, when electron donating groups were present). Hence, PPO AEMs prepared through chloromethylation, as opposed to free radical bromination, were resistant to backbone hydrolysis in alkaline media because each cation-functionalized repeat unit had two electron donating methyl groups rather than a single methyl group. In summary, this paper presents some design rules for preparing mechanically stable poly(arylene ether) AEMs from low cost, commercially available polymers for alkaline electrochemical devices.

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Synthesis and properties of alkaline stable pyridinium containing anion exchange membranes

Cited by 43 publications

References 35 publications

Anion‐Exchange Membranes for Fuel Cells: Synthesis Strategies, Properties and Perspectives

Anion‐Exchange Membranes for Fuel Cells: Synthesis Strategies, Properties and Perspectives

Synthesis and characterization of benzimidazolium-functionalized polysulfones as anion-exchange membranes

Mechanically Stable Poly(arylene ether) Anion Exchange Membranes Prepared from Commercially Available Polymers for Alkaline Electrochemical Devices

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