Amorphous‐Crystalline PSnPEOn Heteroarm Star Copolymers: Crystallinity and Crystallization Kinetics

Koutsopoulou, Eleni; Tsitsilianis, Constantinos

doi:10.1002/macp.200400120

Cited by 3 publications

(2 citation statements)

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“…To achieve HEX cylindrical morphology with P3DDT (or P3HT) matrix, one can use different macromolecular architecture from linear block copolymer, because the molecular architecture of a block copolymer is one of the important parameters to tune morphology and thermal properties. − Among various macromolecular architectures, miktoarm star copolymer is a star polymer that consists of heteroarms with different chemical composition or molecular weight, and has attracted great interest for its distinct behavior compared with corresponding linear block copolymers. − Goseki et al synthesized A 2 B miktoarm star copolymer composed of two polystyrene (PS) arms and one polyhedral oligomeric silsesquioxane-containing poly(methacrylate) (PMAPOSS). Cylindrical microdomains of the PMAPOSS were obtained due to curvature effect at the interface, while these microdomains were not observed in linear PS- b -PMAPOSS diblock copolymers.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Characterization of [Poly(3-dodecylthiophene)]₂Poly(methyl methacrylate) Miktoarm Star Copolymer

et al. 2015

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We have introduced a facile synthetic route for well-defined [poly(3-dodecylthiophene)] 2 poly(methyl methacrylate) miktoarm star copolymer (P3DDT 2 PMMA) by using a click reaction. For this purpose, PMMA with two ethynyl groups (PMMA-(≡) 2 ) and ω-azidopropyl-P3DDT were synthesized. We found that the use of alkyl linker (here, propyl group) between P3DDT and azido group is very essential to minimize the steric hindrance arising from bulky side group in P3DDT during the click reaction. When we employed a slightly excess amount of the ω-azidopropyl-P3DDT, we obtained a well-defined P3DDT 2 PMMA with a narrow molecular weight distribution (polydispersity index <1.20) after selective removal of the unreacted ω-azidopropyl-P3DDT in a crude product by using column chromatography. We also investigated self-assembled structure of P3DDT 2 PMMA by small-angle X-ray scattering (SAXS) and transmission electron microscopy (TEM). P3DDT 2 PMMA with weight fraction of P3DDT block (w P3DDT ) of 0.33 had lamellar microdomains, while a linear diblock copolymer (P3DDT-b-PMMA) with w P3DDT = 0.37 showed cylindrical microdomains. Also, P3DDT 2 PMMA with w P3DDT = 0.59 showed the HEX cylindrical microdomains of PMMA in the P3DDT matrix, whereas P3DDT-b-PMMA with w P3DDT = 0.56 exhibited lamellar microdomains. More interestingly, P3DDT 2 PMMA with w P3DDT of 0.76 showed hexagonally packed PMMA cylinders in the P3DDT matrix at molten state, and this morphology was maintained even after crystallization of the P3DDT block. This behavior is quite different from linear P3DDT-b-PMMA diblock with the same weight fraction of P3DDT because the latter shows fibril structures after P3DDT crystallization. These results imply that controlling the molecular architecture is an effective way to tune the morphology of P3AT-containing block copolymers. ■ INTRODUCTIONRegioregular poly(3-alkylthiophene) (P3AT) is one of the most attractive semicrystalline polymers due to its high charge carrier mobility and good solubility in organic solvents. 1−3 To achieve high performance organic electronic devices, one challenge is fabrication of P3AT nanostructures with nanometer length scale. 4,5 For this purpose, various block copolymers consisting of P3AT and coil blocks have been synthesized 6−15 because of their self-assembly ability to form periodic nanostructures. 16−18 However, most poly(3-hexylthiophene) (P3HT)-containing block copolymers usually exhibit only fibril morphology due to strong rod/rod interaction of P3HT. 18−22 In the rod−coil block copolymer system, the phase behavior is determined by the competition between rod/rod interaction (μ) of rod block and the segregation power (governed by the Flory's segmental interaction parameter χ) between rod and coil blocks. 23−25 These two factors are adjusted by varying the composition of each block or tuning the crystallinity of the rod moiety. Some research groups used P3AT with longer (or bulkier) alkyl side chain than P3HT to depress the crystallization of the rod block. Ho et al. 26 reported various na...

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Section: Introductionmentioning

confidence: 99%

Synthesis and Characterization of [Poly(3-dodecylthiophene)]₂Poly(methyl methacrylate) Miktoarm Star Copolymer

et al. 2015

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“…As known, for linear and crystalline polymers, it is possible that the LB deposition might lead to some changes of the orientation 38 and crystallinity 39 of the chains but does not affect much less ordered polymers such as star polymers. 40 Moreover, previous studies in our group have utilized X-ray reflectivity to study Langmuir monolayers of branched polymers at the air/water interface in comparison to the LB monolayer. 41,42 The results showed that the organization or assembly of the star polymers is not affected by the transfer process with the star polymers becoming somewhat squashed after transferring to the air/solid interface as suggested in this study as well (Figure 5).…”

Section: ■ Introductionmentioning

confidence: 99%

Multiresponsive Star-Graft Quarterpolymer Monolayers

Ledin

Iatridi

et al. 2015

Macromolecules

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Multifunctional star-graft quarterpolymers PS n [P2VPb-(PAA-g-PNIPAM)] n with two different arm types, shorter PS arms and longer P2VP-b-PAA block copolymer arms with grafted PNIPAM chains, were studied in terms of their ability to form micellar structures at the air/water and air/solid interfaces. Because of the pH-dependent ionization of P2VP and PAA blocks, as well as thermoresponsiveness of PNIPAM chains, these multifunctional stars have multiple responsive properties to pH, temperature, and ionic strength. We observed that the molecular surface area of the stars is the largest at basic pH, when the PAA blocks are strongly charged and extended, and PNIPAM chains are spread at the interface. At acidic conditions, the molecular surface area is the smallest because the P2VP blocks submerge into the water subphase and the PAA blocks are contracted and form hydrogen bonding with grafted PNIPAM chains. The molecular surface area of the stars at the air/water interface gradually increases at elevated temperature. We suggest that the transition across lower critical solution temperature (LCST) results in the emerging of PNIPAM chains from the water subphase to the interface due to the hydrophilic to hydrophobic transition. Moreover, at higher surface pressure, the stars tend to form intermolecular micellar aggregates above LCST. The graft density of PNIPAM chains as well as the arm number was also found to have strong effects on the thermo-and pH-response. Overall, this study demonstrates that the star block copolymer conformation and aggregation are strongly dependent on the intramolecular interactions between different blocks and spatial distribution of the arms, which can be controlled by the external conditions, including pH, temperature, ionic strength, and surface pressure.

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Star-shaped polymers having PEO arms

Łapienis

2009

Progress in Polymer Science

224

163

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Amorphous‐Crystalline PS_nPEO_n Heteroarm Star Copolymers: Crystallinity and Crystallization Kinetics

Cited by 3 publications

References 38 publications

Synthesis and Characterization of [Poly(3-dodecylthiophene)]₂Poly(methyl methacrylate) Miktoarm Star Copolymer

Synthesis and Characterization of [Poly(3-dodecylthiophene)]₂Poly(methyl methacrylate) Miktoarm Star Copolymer

Multiresponsive Star-Graft Quarterpolymer Monolayers

Star-shaped polymers having PEO arms

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Amorphous‐Crystalline PSnPEOn Heteroarm Star Copolymers: Crystallinity and Crystallization Kinetics

Cited by 3 publications

References 38 publications

Synthesis and Characterization of [Poly(3-dodecylthiophene)]2Poly(methyl methacrylate) Miktoarm Star Copolymer

Synthesis and Characterization of [Poly(3-dodecylthiophene)]2Poly(methyl methacrylate) Miktoarm Star Copolymer

Multiresponsive Star-Graft Quarterpolymer Monolayers

Star-shaped polymers having PEO arms

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Amorphous‐Crystalline PS_nPEO_n Heteroarm Star Copolymers: Crystallinity and Crystallization Kinetics

Synthesis and Characterization of [Poly(3-dodecylthiophene)]₂Poly(methyl methacrylate) Miktoarm Star Copolymer

Synthesis and Characterization of [Poly(3-dodecylthiophene)]₂Poly(methyl methacrylate) Miktoarm Star Copolymer