Structural effects of polyethers and ionic liquids in their binary mixtures on lower critical solution temperature liquid-liquid phase separation

Kodama, Kazuhisa; Tsuda, Ryohei; Niitsuma, Kazuyuki; Tamura, Takashi; Ueki, Takeshi; Kokubo, Hisashi; Watanabe, Masayoshi

doi:10.1038/pj.2010.140

Cited by 85 publications

(116 citation statements)

References 60 publications

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“…20 C1C3imTFSI has also been investigated as a catalyst for the hydroformylation of alkenes, 21 as an attractive medium for electrodeposition of tantalum, 22 and as a solvent for extraction of aromatic compounds from aliphatic hydrocarbons. 23 Dlubek et al studied C1C3imTFSI using PALS (position annihilation lifetime spectroscopy) and reported a glass transition at a temperature T g ¼ 187 K, a melting transition at a temperature T c ¼ 200 K, and a significant increase in the hole free volume fraction, which determines the temperature-dependence of viscosity, from 0.023 at 185 K to 0.17 at 430 K. 24 Xiao et al have shown that the asymmetry of the C1C3imTFSI cation plays an important role in setting the low-frequency vibrational dynamics of the IL and in determining its relatively low melting point. 25 Pure C1C3imTFSI has been reported with an ionic conductivity of 7.42 Â 10 À3 S cm À1 at 30 C. 26 When doped with the salt LiTFSI in a 1 : 1 molar ratio, the material is reported to exhibit a markedly lower ionic conductivity (e.g.…”

Section: -19mentioning

confidence: 99%

Ionic liquid-nanoparticle hybrid electrolytes

et al. 2012

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We investigate physical and electrochemical properties of a family of organic-inorganic hybrid electrolytes based on the ionic liquid 1-methyl-3-propylimidazolium bis(trifluoromethanesulfone) imide covalently tethered to silica nanoparticles (SiO 2 -IL-TFSI). The ionic conductivity exhibits a pronounced maximum versus LiTFSI composition, and in mixtures containing 13.4 wt% LiTFSI, the room-temperature ionic conductivity is enhanced by over 3 orders of magnitude relative to either of the mixture components, without compromising lithium transference number. The SiO 2 -IL-TFSI/LiTFSI hybrid electrolytes are thermally stable up to 400 C and exhibit tunable mechanical properties and attractive (4.25V) electrochemical stability in the presence of metallic lithium. We explain these observations in terms of ionic coupling between counterion species in the mobile and immobile (particle-tethered) phases of the electrolytes.

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Section: -19mentioning

confidence: 99%

Ionic liquid-nanoparticle hybrid electrolytes

et al. 2012

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“…11,12 For example, poly(N-isopropylacrylamide) (PNIPAm) shows an upper critical solution temperature (UCST) phase transition in certain ILs, which is a completely opposite phenomenon to that observed in aqueous solutions. 13 In contrast, certain polymethacrylates [14][15][16] or polyether derivatives [17][18][19] are found to exhibit lower critical solution temperature (LCST) phase behavior in ILs. Phase transitions of polymers in nonvolatile and thermally stable ILs can afford long-term stable smart materials without solvent evaporation.…”

Section: Introductionmentioning

confidence: 93%

Temperature and light-induced self-assembly changes of a tetra-arm diblock copolymer in an ionic liquid

Usui

Kitazawa

et al. 2015

Polym J

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A tetra-arm diblock copolymer ([PEG-b-P(AzoMA-r-NIPAm)] 4 ) was synthesized by reversible addition-fragmentation chain transfer copolymerization of N-isopropylacrylamide (NIPAm) and 4-phenylazophenyl methacrylate (AzoMA), initiating from the ends of functionalized tetra-arm polyethylene glycol (tetra-PEG). The resulting tetra-arm diblock copolymer consists of two segments: tetra-PEG (the center block; compatible with 1-butyl-3-methylimidazolium hexafluorophosphate ([C 4 mim]PF 6 )) and P(AzoMA-rNIPAm) (the end blocks; temperature-and photosensitive compatibility with [C 4 mim]PF 6 due to photoresponsive upper critical solution temperature phase behavior). We found that [PEG-b-P(AzoMA-r-NIPAm)] 4 underwent high-temperature unimer and lowtemperature micelle (upper critical micellization temperature (UCMT)) transitions in [C 4 mim]PF 6 . The UCMT of the tetra-arm diblock copolymer depended on photoisomerization states of the azobenzene groups within the copolymer. The UCMT of the trans-form polymer in dark conditions was higher than that of the cis-form polymer under UV-light irradiation. We demonstrated photoinduced self-assembly changes of the tetra-arm diblock copolymer in [C 4 mim]PF 6 at a 'bistable' temperature. Reversible photoinduced unimer/micelle transitions were also demonstrated. INTRODUCTIONIonic liquids (ILs) are ambient temperature molten salts and have attracted considerable attention because of their unique properties such as nonvolatility, nonflammability, thermal and chemical stability and high ionic conductivity. 1-8 Composite materials consisting of polymers and ILs can realize useful materials such as polymer electrolyte membranes, gas separation membranes and catalytic membranes. 9,10 Furthermore, we previously focused on stimuliresponsive polymers in ILs. 11,12 For example, poly(N-isopropylacrylamide) (PNIPAm) shows an upper critical solution temperature (UCST) phase transition in certain ILs, which is a completely opposite phenomenon to that observed in aqueous solutions. 13 In contrast, certain polymethacrylates 14-16 or polyether derivatives 17-19 are found to exhibit lower critical solution temperature (LCST) phase behavior in ILs. Phase transitions of polymers in nonvolatile and thermally stable ILs can afford long-term stable smart materials without solvent evaporation. Recently, we developed photoresponsive polymers in ILs by copolymerization of an azobenzene-containing monomer, 4-phenylazophenyl methacrylate (AzoMA), with either NIPAm 20 or benzyl methacrylate 21 as the main monomer.Self-assembly of block copolymer in an IL is another fascinating topic from the materials science point of view. 22-26 Block copolymer membranes or dilute solutions exhibit useful nanostructures due to intramolecular segregation. Lodge and coworkers reported polybutadiene-block-poly(ethylene oxide) (PB-b-PEO) block copolymer selfassembly in 1-butyl-3-methylimidazolium hexafluorophosphate ([C 4 mim]PF 6 ). 27 They found that PB-b-PEO self-assembled into micelles with an IL-insoluble PB core surrounded by P...

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“…Three polyethers with various fractions of PEO were synthesized as previously reported, 53 with the molecular weights (M n ) and polydispersity indexes (PDI) presented in Table 1 Sample Preparation. Polymer/water and polymer/EAN samples with various polymer concentrations (0.1 and 1 wt %) were stirred overnight in a sealed glass vial at room temperature prior to measurements.…”

Section: ■ Experimental Sectionmentioning

confidence: 99%

Adsorption of Polyether Block Copolymers at Silica–Water and Silica–Ethylammonium Nitrate Interfaces

et al. 2015

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Atomic force microscope (AFM) force curves and images are used to characterize the adsorbed layer structure formed by a series of diblock copolymers with solvophilic poly(ethylene oxide) (PEO) and solvophobic poly(ethyl glycidyl ether) (PEGE) blocks at silica-water and silica-ethylammoniun nitrate (EAN, a room temperature ionic liquid (IL)) interfaces. The diblock polyethers examined are EGE109EO54, EGE113EO115, and EGE104EO178. These experiments reveal how adsorbed layer structure varies as the length of the EO block varies while the EGE block length is kept approximately constant; water is a better solvent for PEO than EAN, so higher curvature structures are found at the interface of silica with water than with EAN. At silica-water interfaces, EGE109EO54 forms a bilayer and EGE113EO115 forms elongated aggregates, while a well-ordered array of spheres is present for EGE104EO178. EGE109EO54 does not adsorb at the silica-EAN interface because the EO chain is too short to compete with the ethylammonium cation for surface adsorption sites. However, EGE113EO115 and EGE104EO178 do adsorb and form a bilayer and elongated aggregates, respectively.

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Structural effects of polyethers and ionic liquids in their binary mixtures on lower critical solution temperature liquid-liquid phase separation

Cited by 85 publications

References 60 publications

Ionic liquid-nanoparticle hybrid electrolytes

Ionic liquid-nanoparticle hybrid electrolytes

Temperature and light-induced self-assembly changes of a tetra-arm diblock copolymer in an ionic liquid

Adsorption of Polyether Block Copolymers at Silica–Water and Silica–Ethylammonium Nitrate Interfaces

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