Towards the gemini cation anion exchange membranes by nucleophilic substitution reaction

Zhang, Jianjun; He, Yubin; Liang, Xian; Ge, Xiaolin; Zhu, Yuan; Hu, Min; Yang, Zhengjin; Wu, Liang; Xu, Tongwen

doi:10.1007/s40843-018-9397-0

Cited by 19 publications

(12 citation statements)

References 52 publications

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“…52,53 The To compare our membranes with recently reported AEMs, we summarize the AEMFCs peak power densities as a function of room temperature OH − conductivities for recently reported AEMs that based on similar aryl ether-containing polyaromatics backbone (Figure 4g and Table S2). 9,20,21,47,[54][55][56][57][58][59][60][61][62][63][64][65][66][67][68] And our QA38PPO-P membrane show a competitive OH − conductivity and fuel cell performance among these AEMs. This highlights the advantages of developing AEMs containing well-defined cation-dipole interaction networks, which can form inter-connected ionic channels that facilitate ion transport.…”

Section: Simulation Studiesmentioning

confidence: 89%

Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH⁻conduction

Zhang

et al. 2021

AIChE Journal

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Precise control over polyelectrolyte architecture, engineered for self-assembly of ion-conducting channels, is of fundamental and technological importance to many fields, for example, fuel cells and redox flow batteries and electrodialysis. Building on recent advances with the supramolecular chemistry, we introduce inter/intramolecular cation-dipole interactions between pendent quaternary ammoniums cations and polar polyethylene glycol grafts in an anion-exchange membrane (AEM). Such interactions lead to desirable, ordered ion-conducting pathways when in the membrane form. Comparison of the results of molecular dynamics simulation with 1 H NMR and nano-scale microscopy analyses show that the cation-dipole interactions enhance self-assembly and the formation of interconnected ionic network domains, providing three-dimensional pathways for both water and ion transport. The resultant AEM exhibits high OH − conductivity (49 mS cm −1 at 30 C) and a completive peak power density of 622 mW cm −2 at 70 C when tested in a H 2 /O 2 single-cell alkaline membrane fuel cell.

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Section: Simulation Studiesmentioning

confidence: 89%

Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH⁻conduction

Zhang

et al. 2021

AIChE Journal

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“…The side chains promote the formation of interconnected ion‐conducting channel, which results in high ion conductivity. On this basis, we further optimized the side chain structure by increasing the number (two or three) of the cationic groups (Figures 4c, 4d), [ 32‐33 ] and found that the multi‐functionalized side chains will aggregate together easier to form the well‐connected ion‐conducting channel, the ion transfer efficiency was much higher when introducing three cations in side chain, with hydroxide conductivity of 69 mS/cm at room temperature, which is comparable to that of the proton exchange membrane Nafion. It demonstrated a facile but efficient strategy to design highly OH − conductive IEMs.…”

Section: Ion Exchange Membrane Preparationsmentioning

confidence: 99%

Ion Exchange Membrane “ABC” – A Key Material for Upgrading Process Industries

Wang¹,

Yang²,

Wu³

et al. 2021

Chin. J. Chem.

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Who is the most influenced person in your academic career? My supervisor academician Binglin He. How do you get into the field of ion exchange membrane? I got in contact with ion exchange membranes during my postdoc research in Nankai University under the guidance of Prof. Binglin He. My supervisor is known as "father of China's ion exchange resin". But in the synthesis of ion exchange resin, the resin pellets larger than 6 mm or smaller than 4 mm cannot be used and are directly discarded. Therefore, Prof. He asked me to explore how to convert them into membrane shape so as to reuse the wasted resin. Since then I entered the field of ion exchange membrane. In your opinion, what is the most promising ion exchange membrane in the next couple years? Alkaline stable anion-exchange membranes that can be used for hydrogen production from electrolytic water splitting, fuel cells, and electrochemical ammonia synthesis, etc. Besides the fundamental research, why do you spend a lot time and energy to industrialize the ion exchange membrane? Ion exchange membrane is relatively a narrow product in the field of separation membrane materials. Nowadays, there are tremendous demands of these kind of membranes due to the stricter regulations on wastewater disposal. However, the development of ion exchange membranes in China lags far behind that in other developed countries. As a scientist in this filed, I believe that I have the responsibility to promote the development and advancement of our domestic ion exchange membrane. For this reason, four licensed patents of us have been transferred for industrialization and more than 400 000 m 2 of membranes were used per year in various industries. What is the greatest honor for your academic achievement? My students are my greatest honor. I am proud of more and more students being graduated from my lab, who have played/will play important roles in making our country stronger. What's your hobbies? Walking, playing basketball and cards.

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“…Quaternary ammonium-functionalized AEMs are the most widely researched because of their good hydrophilicity and high anion conductivity [27][28][29][30]. Generally, they can be synthesized by two reaction routes: (1) post-halomethylation of polymer precursors followed by quaternization [31][32][33] or (2) direct polymerization of quaternary ammonium-or amine-containing monomers [34][35][36].…”

Section: Introductionmentioning

confidence: 99%

Fluorinated poly(fluorenyl ether)s with linear multi-cationic side chains for vanadium redox flow batteries

Chen

Wang

et al. 2020

Sci. China Mater.

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The cationic group distribution along the polymeric backbones of anion exchange membranes (AEMs) has significant influence on their microscopic morphology and anion conductivity. To develop high-performance AEMs for vanadium redox flow batteries (VRFBs), a series of poly (fluorenyl ether) samples bearing di-and tri-quaternary ammonium side chains with similar ion exchange capacities (IECs) were synthesized by grafting cationic alkyl chains with tertiary amine-containing poly(fluorenyl ether) precursors. The experimental results indicate that the introduction of the multi-cationic side chains facilitates the formation of microphase-separated morphologies and enhances anion conductivity. Moreover, the number of spacer atoms between the quaternary ammonium groups on the side chains affects the water uptake of the membranes, thus complicating the relationship between the density of cationic group distribution and anion conductivity. The poly(fluorenyl ether)s with dicationic side chains and six spacing atoms (DQA-PFE-C6) showed the highest anion conductivity. A VRFB assembled with DQA-PFE-C6 exhibited a maximum power density of 239.80 mW cm −2 at 250 mA cm −2 , which is significantly higher than a VRFB assembled with Nafion 212. Therefore, side chain engineering is an effective chemical approach to enhance the properties of AEMs for VRFB applications.

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Towards the gemini cation anion exchange membranes by nucleophilic substitution reaction

Cited by 19 publications

References 52 publications

Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH⁻conduction

Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH⁻conduction

Ion Exchange Membrane “ABC” – A Key Material for Upgrading Process Industries

Fluorinated poly(fluorenyl ether)s with linear multi-cationic side chains for vanadium redox flow batteries

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Towards the gemini cation anion exchange membranes by nucleophilic substitution reaction

Cited by 19 publications

References 52 publications

Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH−conduction

Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH−conduction

Ion Exchange Membrane “ABC” – A Key Material for Upgrading Process Industries

Fluorinated poly(fluorenyl ether)s with linear multi-cationic side chains for vanadium redox flow batteries

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Product

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Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH⁻conduction

Cation–dipole interaction that creates ordered ion channels in an anion exchange membrane for fastOH⁻conduction