Interfacial Crystallization‐Driven Assembly of Conjugated Polymers/Quantum Dots into Coaxial Hybrid Nanowires: Elucidation of Conjugated Polymer Arrangements by Electron Tomography

Jin, Seon-Mi; Kim, Inhye; Lim, Jung Ah; Ahn, Hyungju; Lee, Eunji

doi:10.1002/adfm.201504964

Cited by 29 publications

(35 citation statements)

References 63 publications

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“…The resulting nanostructures show colloidal stability due to the presence of the solvent swollen corona and have been exploited for a variety of uses including the delivery of therapeutic cargoes in nanomedicine 2 , as additives for friction reduction 3 , fillers for composite reinforcement 4 or for the formation of nanoscopic arrays using optical tweezers 5 . However, although recent advances have described examples of fibre-like micelles with novel photophysical characteristics 6 7 , their assembly into complex semiconducting particles, bundles and branched superstructures 8 9 10 11 , and their fabrication of coaxial nanowires with quantum dots 12 13 , ordered two-dimensional assemblies at interfaces 14 and solar cells 15 , the evaluation of their potential as functional electroactive materials in devices is virtually unexplored 14 15 ; specifically, uniform samples of low length dispersity have not been investigated.…”

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confidence: 99%

Uniform electroactive fibre-like micelle nanowires for organic electronics

et al. 2017

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Micelles formed by the self-assembly of block copolymers in selective solvents have attracted widespread attention and have uses in a wide variety of fields, whereas applications based on their electronic properties are virtually unexplored. Herein we describe studies of solution-processable, low-dispersity, electroactive fibre-like micelles of controlled length from π-conjugated diblock copolymers containing a crystalline regioregular poly(3-hexylthiophene) core and a solubilizing, amorphous regiosymmetric poly(3-hexylthiophene) or polystyrene corona. Tunnelling atomic force microscopy measurements demonstrate that the individual fibres exhibit appreciable conductivity. The fibres were subsequently incorporated as the active layer in field-effect transistors. The resulting charge carrier mobility strongly depends on both the degree of polymerization of the core-forming block and the fibre length, and is independent of corona composition. The use of uniform, colloidally stable electroactive fibre-like micelles based on common π-conjugated block copolymers highlights their significant potential to provide fundamental insight into charge carrier processes in devices, and to enable future electronic applications.

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confidence: 99%

Uniform electroactive fibre-like micelle nanowires for organic electronics

et al. 2017

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“…N-type quantum dots or fullerenes and p-type P3HT-containing BCPs have been used to form hybrid nanowires by solution processing routes. [256][257][258] 6.5 Applications of BCP micelles for lubrication and composite reinforcement, and as stabilizers.…”

Section: Etch Resists In Nanolithography and Functional Nanostructurementioning

confidence: 99%

50th Anniversary Perspective: Functional Nanoparticles from the Solution Self-Assembly of Block Copolymers

et al. 2017

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This Perspective outlines recent advances concerning the formation and potential uses of block copolymer micelles, a class of soft matter-based nanoparticles of growing importance. As a result of rapidly expanding interest since the mid 1990s, substantial advances have been reported in terms of the development of morphological diversity and complexity, control over micelle dimensions, scale up, and applications in a range of areas from nanocomposites to nanomedicine.

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“…During the dip-coating process, the solvent properties of the top phase solution strongly affected the resulting lm formation as well as the crystallization behavior of the conjugated polymer. 27,28 The solvent evaporation rate is one of the most critical factors controlling the crystallinity of a polymer lm prepared by dip coating. A high boiling point solvent can facilitate crystallization among polymer chains by prolonging the solvent evaporation time.…”

Section: The Secondary Solvent Addition Processmentioning

confidence: 99%

“…Numerous studies have reported that solvent additive-assisted solution processes can perform better than systems prepared without a solvent additive. 27,34,35 We tested solvent additives in the biphasic dip-coating method in two different ways ( Fig. 2b): (1) by oating the solvent additive on a polymer-dissolving top-phase solution (oating method); and (2) by mixing the solvent additive with the polymerdissolving solution before forming a biphasic system (mixing method).…”

Section: The Secondary Solvent Addition Processmentioning

confidence: 99%