Ionic Liquid Crystalline Composite Membranes Composed of Smectic Imidazolium Hydrogen Sulfate and Polyvinyl Alcohol for Anhydrous Proton Conduction

Xie, Wenting; Tan, Shuai; Yang, Jie; Ji, Luo; Wang, Caihong; Wu, Yong

doi:10.1021/acs.iecr.0c00315

Cited by 10 publications

(7 citation statements)

References 37 publications

(55 reference statements)

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“…Ref. : PVA/MPPIS; 81 PVA/nZnO; 75 PVA/DBEG‐G‐SiO 2 ; 82 PVA/SSA/GO; 83 PVA/Sulfonated nSiO 2 /GA; 70 PVA/SiWA/nSiO 2 /SSA; 73 SPEEK/PVA@GO‐NF; 66 PVA/PAMPS‐ g ‐FSN/GA; 84 Propane sultone/PVA/SSA/GO; 23 PVA/PAN‐ co ‐PSSA/PAMPS‐Si; 68 PVA/TEOS/SSA; 85 PVA/nSiO 2 /SSA; 86 PVA/SCNT/SSA; 69 PVA/SGO; 74 H 3 PO 4 ‐imbibed PAM/PVA; 87 HPA/PVA‐ g ‐Aam (GA crosslinked); 88 PVA/PSSA‐SiO 2 /SSA/GA; 71 PVA/SSA; 77 SPEEK/PVA/TEOS; 67 PPVA/PHB/SiO 2 ‐P NPs; 80 PVA/SPANi‐GO; 89 PVA/PAMPS/ZIF; 78 and PVDF/PPVA/nTiO 2 76 . Abbreviations: Aam, acrylamide; DBEG, 1,4‐diglycidyl butane ether; FSN, fumed silica nanoparticles; GA, glutaraldehyde; GO, graphene oxide; HPA, heteropolyacid (H 3 PW 12 O 40 ); MPPIS, liquid crystal: 1‐methyl‐3‐[6‐[4‐(trans‐4‐pentylcyclohexyl)‐ phenoxy]hexyl]imidazolium hydrogen sulfate; PAM, polyacrylamide; PFSA, perfluorosulfonic acid; PPVA, phosphonated PVA; PVDF, poly(vinylidene difluoride); SCNT, sulfonated carbon nanotubes; SiO 2 ‐P NPs: phosphonated silica nanoparticles; SiWA, silicotungstic acid; SPEEK, sulfonate poly(ether ketone); SSA, sulfosuccinic acid; TEOS, tetraethyl orthosilicate; ZIF, zeolite‐imidazole framework…”

Section: Pva‐based Membranes For Fuel Cellsmentioning

confidence: 99%

Poly(vinyl alcohol)‐based membranes for fuel cell and water treatment applications: A review on recent advancements

Choudhury

Gohil

Dutta

2021

Polymers for Advanced Techs

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Clean water and energy are two of the most important requirements for human survival. Membrane‐based filtration represents one of the advanced technologies involved in water decontamination; while, polymer electrolyte membrane fuel cells (PEMFCs) are among the frontrunners in the alternative and renewable energy domain. It is evident that membrane‐based processes provide sustainable solution to the ever‐increasing demand of energy and clean water. Over the years, it has been realized that synthetic poly(vinyl alcohol) (PVA) is one of the potential candidates for the development of membranes, owing to its hydrophilicity, barrier property, film forming ability, crosslinking ability, biodegradability, and low cost. These properties have been widely explored for the fabrication of polymer electrolyte membranes for PEMFCs, in order to improve the ionic conductivity and methanol barrier property, as well as, to reduce the membrane fabrication cost. On the other hand, high water solubility and film forming characteristics of PVA have been used for the formation of water treatment membranes, for enhancing the antifouling property and chemical stability. This review provides in‐depth discussions and analyses on the structure and properties of various PVA‐based copolymers, and their applications as membrane materials for PEMFCs (including direct methanol and alkaline fuel cells) and water remediation.

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Section: Pva‐based Membranes For Fuel Cellsmentioning

confidence: 99%

Poly(vinyl alcohol)‐based membranes for fuel cell and water treatment applications: A review on recent advancements

Choudhury

Gohil

Dutta

2021

Polymers for Advanced Techs

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“…5−7 However, the high ion-exchange capacity usually leads to excessive swelling under the hydrated condition and thus affects structural stability and further performance optimization. 8,9 In recent years, porous organic polymers (POPs), such as porous aromatic frameworks (PAFs), polymers of intrinsic microporosity (PIMs), and covalent organic frameworks (COFs), have attracted global attention due to their rigid scaffold structure and tunable pore size. 10−13 The intrinsic nanopores of polymer scaffold not only provide a platform for constructing transport pathways but also exhibit high structural stability even under high ion-exchange capacity 14,15 Current strategies for developing POP-based proton conductors rely on doping with external proton carriers or postmodifications with chlorosulfonic acid.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Therefore, sufficient proton donor groups and acceptors are highly required to obtain high proton conductivity. Conventional polyelectrolytes are based on flexible functional polymers, such as Nafion, sulfonated poly(ether ether ketone) (SPEEK), sulfonated polysulfone (SPS), etc. − However, the high ion-exchange capacity usually leads to excessive swelling under the hydrated condition and thus affects structural stability and further performance optimization. , …”

Section: Introductionmentioning

confidence: 99%

Highly Proton Conductive Phosphoric Acid Porous Organic Polymers via Knitting Method

Zhu

Shi

et al. 2021

Ind. Eng. Chem. Res.

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Phosphoric acid group, which possesses a low energy barrier for proton conduction and high water bonding energy, favors proton conduction and water retention. In this study, a phosphoric acid porous organic polymer (PAPOP) with high proton conductivity was synthesized. The diethyl benzylphosphonate (DBP) monomer and the benzyl monomer were directly knitted via the Friedel–Crafts alkylation reaction to form a porous scaffold. The phosphate ester group on DBP not only enhanced the monomer reactivity but also realized the in situ introduction of the phosphoric acid group precursor during the formation of the porous scaffold. It is found that p-dichloroxylene (DCX) monomer, due to its higher electrophilic activity, is easier to react with DBP and thus easier to introduce phosphoric acid groups. The higher ratio of DCX leads to a more continuous hydrogen-bond network within the scaffold, which facilitates the proton-conducting process. The resultant porous organic polymers exhibited high hydrophilicity and excellent stability in strong acid as well as antiswelling ability in water. The highest ion-exchange capacity reached 2.68 mmol g–1, much higher than that of most reported polymers. The proton conductivity of powders reached the highest value of 7.09 × 10–2 S cm–1 at 348 K and 98% relative humidity.

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“…Ionic liquid crystals, combining the synergistic features of nonvolatile ionic liquids and dynamically ordered liquid crystals, − are promising candidates as efficient and stable electrolytes for providing multiscale channels capable of ion transport. − Previously, we showed that liquid crystal nanostructures could promote Grotthuss-type charge transport in thiolate/disulfide (T – /T 2 )-based smectic electrolytes for DSSCs . The organic T – /T 2 redox, possessing properties of noncorrosion, transparency, and noninhibition to radical polymerization, is promising to rival the traditional iodide/triiodide redox for all-solid-state DSSC preparation .…”

Section: Introductionmentioning

confidence: 99%

All-Solid-State Polymer Electrolyte with Efficiency and Stability Superior to Its Smectic Precursor for Photoelectrochemical Devices

Zhou

Wang

Zhang

et al. 2021

Ind. Eng. Chem. Res.

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All-solid-state electrolytes have attracted wide interest for versatile energy devices owing to their stability improvement toward sustainable applications; however, the low conductivity and interfacial contact remain to be addressed. Herein, a facile method was proposed for preparing superior allsolid-state electrolytes from ionic liquid crystals. A vinylimidazolium thiolate/disulfide redox-based lamellar nanostructured electrolyte showing a smectic mesophase was prepared as a precursor, and flexible polyethylene oxide (PEO) was introduced to gel the smectic domains of the precursor to form a microphase segregation nanostructure. The PEO chains assembled at domain interfaces could significantly improve the charge transport through the smectic domain boundaries in the electrolyte. The dynamic liquid crystal gel was first assembled in a dye-sensitized solar cell (DSSC) to provide good interfacial contact, and then, in situ polymerization was performed to fabricate an all-solid-state electrolyte. The microphase segregation nanostructure was well maintained within the polymerized electrolytes for efficient charge transport. Thus, the all-solid-state electrolytes exhibited ion conductivity, thermal stability, and DSSC efficiency much superior to its smectic precursor despite the loss of fluidity. The work here sheds new light on developing desirable all-solid-state electrolytes from ionic liquid crystals for energy devices.

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Ionic Liquid Crystalline Composite Membranes Composed of Smectic Imidazolium Hydrogen Sulfate and Polyvinyl Alcohol for Anhydrous Proton Conduction

Cited by 10 publications

References 37 publications

Poly(vinyl alcohol)‐based membranes for fuel cell and water treatment applications: A review on recent advancements

Poly(vinyl alcohol)‐based membranes for fuel cell and water treatment applications: A review on recent advancements

Highly Proton Conductive Phosphoric Acid Porous Organic Polymers via Knitting Method

All-Solid-State Polymer Electrolyte with Efficiency and Stability Superior to Its Smectic Precursor for Photoelectrochemical Devices

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