General Pathway toward Crystalline-Core Micelles with Tunable Morphology and Corona Segregation

Schmelz, Joachim; Karg, Matthias; Hellweg, Thomas; Schmalz, Holger

doi:10.1021/nn202638t

Cited by 179 publications

(271 citation statements)

References 61 publications

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“…Seeded-growth of crystallizable BCPs from 1D cylindrical seeds prepared by sonication of long, polydisperse cylinders with a crystalline core provides a recently established route to low dispersity cylindrical micelles of controlled length [18][19][20] and also complex architectures such as block comicelles, [21][22][23] branched cylindrical micelles, 24 and multi-armed micelles. 25 The key to this approach is that the core termini of the seeds remain active to the addition of further BCP unimer, leading to a process that is analogous to a living covalent polymerization of molecular monomers.…”

Section: Seeded Growth Of Pfs Homopolymers With Charged End-groups Usmentioning

confidence: 99%

Two-dimensional assemblies from crystallizable homopolymers with charged termini

et al. 2017

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Section: Seeded Growth Of Pfs Homopolymers With Charged End-groups Usmentioning

confidence: 99%

Two-dimensional assemblies from crystallizable homopolymers with charged termini

et al. 2017

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“…Confinement of polymer systems can be generally classified into three categories according to their confined environments, and they are one, two and three dimensions, respectively. Confined crystallization of polymers has been found in a variety of systems, such as polymer ultrathin films [1][2][3][4][5], polymer blends [6][7][8][9][10], block copolymers [11][12][13][14], polymer droplets [15][16][17], self-assembled polymer nanostructures [18][19][20][21][22], polymers segregated inside nanoporous templates [23][24][25][26][27][28][29] and polymer nanocomposites [30][31][32][33]. In the past few years, the crystallization of polymers or polymer segments confined in ultrathin films (thickness <100 nm), miscible polymer blends and block copolymers has been widely studied for various systems.…”

Section: Introductionmentioning

confidence: 99%

Crystalline and Spherulitic Morphology of Polymers Crystallized in Confined Systems

Xie

Bao

et al. 2017

Crystals

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Due to the effects of microphase separation and physical dimensions, confinement widely exists in the multi-component polymer systems (e.g., polymer blends, copolymers) and the polymers having nanoscale dimensions, such as thin films and nanofibers. Semicrystalline polymers usually show different crystallization kinetics, crystalline structure and morphology from the bulk when they are confined in the nanoscale environments; this may dramatically influence the physical performances of the resulting materials. Therefore, investigations on the crystalline and spherulitic morphology of semicrystalline polymers in confined systems are essential from both scientific and technological viewpoints; significant progresses have been achieved in this field in recent years. In this article, we will review the recent research progresses on the crystalline and spherulitic morphology of polymers crystallized in the nanoscale confined environments. According to the types of confined systems, crystalline, spherulitic morphology and morphological evolution of semicrystalline polymers in the ultrathin films, miscible polymer blends and block copolymers will be summarized and reviewed.

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“…The WAXS pattern for P3C7Se 18 -b -PS 125 micelles dropcast from n BuOAc was found to be similar to that for the P3C7Se 18 [ 68 ] Crystalline P3AT fi lms are known to exhibit two different crystal structures designated type-1 and type-2. [ 68,81 ] The type-1 polymorph exhibits thicker layers and a lower degree of alkyl chain interdigitation by WAXS analysis.…”

Section: Waxs Studies Of P3c7se 18 -B -Ps 125 Diblock Copolymer Micellesmentioning

confidence: 99%

“…The solution self-assembly of amphiphilic "coil-coil" diblock copolymers, where both blocks are amorphous and behave as random coils in solution has been well studied and offers an important "bottom-up" route to nanoscale soft materials with applications such as drug delivery vehicles, nanoreactors, templates, and stimuli-responsive has been demonstrated for a wide variety of asymmetric diblock copolymers containing crystallizable core-forming segments including polyethylene, [ 8,[17][18][19] poly(ethylene oxide), [ 20 ] poly(ε-caprolactone), [ 21,22 ] poly(ε-caprolactoneb -L -lactide), [ 23 ] polylactide, [ 7,24 ] polyacrylonitrile, [ 25 ] poly(ferrocenyldimethylsilane) (PFS), [ 26,27 ] poly(ferrocen yldimethylgermane), [ 28 ] poly(ferrocenyldiethylsilane), [ 29 ] poly(perfl uoro-octylethylmethacrylate), [ 30 ] cyclic polypeptoids, [ 31 ] and even smectic liquid crystalline polymers. [ 32 ] In several cases, it has been demonstrated that the dimensions of micelles formed by CDSA can be controlled by a living process analogous to a living covalent polymerization.…”

Section: Introductionmentioning

confidence: 99%

Fiber‐Like Micelles from the Crystallization‐Driven Self‐Assembly of Poly(3‐heptylselenophene)‐block‐Polystyrene

Kynaston

Gould

Gwyther

et al. 2015

Macro Chemistry & Physics

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The crystallization-driven self-assembly (CDSA) of crystalline-coil polyselenophene diblock copolymers represents a facile approach to nanofi bers with distinct optoelectronic properties relative to those of their polythiophene analogs. The synthesis of an asymmetric diblock copolymer with a crystallizable, π-conjugated poly(3-heptylselenophene) (P3C7Se) block and an amorphous polystyrene (PS) coblock is described. CDSA was performed in solvents selective for the PS block. Based on transmission electron microscopy (TEM) analysis, P3C7Se 18 -b -PS 125 formed very long (up to 5 μm), highly aggregated nanofi bers in n -butyl acetate ( n BuOAc) whereas shorter (ca. 500 nm) micelles of low polydispersity were obtained in cyclohexane. The micelle core widths in both solvents determined from TEM analysis (≈ 8 nm) were commensurate with fully-extended P3C7Se 18 chains (estimated length = 7.1 nm). Atomic force microscopy (AFM) analysis provided characterization of the micelle cross-section including the PS corona (overall micelle width ≈ 60 nm). The crystallinity of the micelle cores was probed by UV-vis and photoluminescence (PL) spectroscopy and wide-angle X-ray scattering (WAXS).

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General Pathway toward Crystalline-Core Micelles with Tunable Morphology and Corona Segregation

Cited by 179 publications

References 61 publications

Two-dimensional assemblies from crystallizable homopolymers with charged termini

Two-dimensional assemblies from crystallizable homopolymers with charged termini

Crystalline and Spherulitic Morphology of Polymers Crystallized in Confined Systems

Fiber‐Like Micelles from the Crystallization‐Driven Self‐Assembly of Poly(3‐heptylselenophene)‐block‐Polystyrene

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