A Latex‐<scp>B</scp>ased Route to Disperse Carbon Nanotubes in Poly(2,6‐<scp>D</scp>imethyl‐1,4‐<scp>P</scp>henylene Ether)/<scp>P</scp>olystyrene Blends

Grossiord, Nadia; Noordover, Baj Bart; Miltner, HE; Hoeks, TL Theo; Alexandre, V; Loos, Joachim; Mele, van B; Meuldijk, J.; Koning, CE Cor

doi:10.1002/mame.201300105

Cited by 4 publications

(1 citation statement)

References 37 publications

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“…CNTs can be incorporated into insulating polymers to make conductive composites by a variety of preparation techniques, including ball-milling, melt-mixing, slot-die-coating, and spin-coating, but most of them suffer from limitations in film homogeneity and thickness control. − Meanwhile, some researchers have tried to use solvent-based latex particle dispersions as a starting point for producing thin films and achieving an improved assembly of carbon nanotubes in a conductive network and lower percolation threshold. , In this so-called latex technology, small latex particles are mixed with ultrasonicated CNTs in a suitable solvent, where the large size difference of the CNTs and the latex particles are thought to aid the assembly of CNTs during the production of the final solid film. , Indeed, film formation of mixtures of latex particles and carbon nanotubes often results in a more highly conductive composite film and reduced percolation threshold, which has been explained in terms of so-called depletion interactions between the CNTs due to the presence of the much smaller latex particles …”

Section: Introductionmentioning

confidence: 99%

Bimodal Latex Effect on Spin-Coated Thin Conductive Polymer–Single-Walled Carbon Nanotube Layers

Moradi¹,

Angoitia²,

Berkel

et al. 2015

Langmuir

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We synthesize two differently sized poly(methyl methacrylate-co-tert-butyl acrylate) latexes by emulsion polymerization and mix these with a sonicated single-walled carbon nanotube (SWCNT) dispersion, in order to prepare 3% SWCNT composite mixtures. We spin-coat these mixtures at various spin-speed rates and spin times over a glass substrate, producing a thin, transparent, solid, conductive layer. Keeping the amount of SWCNTs constant, we vary the weight fraction of our smaller 30-nm latex particles relative to the larger 70-nm-sized ones. We find a maximum in the electrical conductivity up to 370 S/m as a function of the weight fraction of smaller particles, depending on the overall solid content, the spin speed, and the spin time. This maximum occurs at 3-5% of the smaller latex particles. We also find a more than 2-fold increase in conductivity parallel to the radius of spin-coating than perpendicular to it. Atomic force microscopy points at the existence of lanes of latex particles in the spin-coated thin layer, while large-area transmission electron microscopy demonstrates that the SWCNTs are aligned over a grid fixed on the glass substrate during the spin-coating process. We extract the conductivity distribution on the surface of the thin film and translate this into the direction of the SWCNTs in it.

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Section: Introductionmentioning

confidence: 99%

Bimodal Latex Effect on Spin-Coated Thin Conductive Polymer–Single-Walled Carbon Nanotube Layers

Moradi¹,

Angoitia²,

Berkel

et al. 2015

Langmuir

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Latex Technology for Conductive Polymer Nanocomposites

Grossiord

Hermant

2016

Encyclopedia of Polymer Science and Technology

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Latex technology is a unique and scalable process whereby polymeric nano‐ and microcomposites can be prepared. The use of water as a processing media and minimal energy requirements make the process environmentally friendly. Furthermore, the process is applicable to various fillers and polymers. In this article, special attention is paid to various analytical methods with which the process can be monitored and assessed, as well as to strategies to optimize the final composites properties. Focus is placed on conductive nanocomposites prepared using carbon nanotubes and the latex technology process. A brief introduction to the percolation theory of rod‐like fillers is given; the influence that the filler and matrix properties have on this theory and the simulated conductive behavior are also addressed. Methods to manipulate the final composite properties through the clever use of chemical and physical adjustments are described. Finally, applications of materials prepared using latex technology are also discussed.

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Physical Properties of Hydrogen‐Bonded Polymers

2018

Hydrogen Bonding in Polymeric Materials

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A Latex‐Based Route to Disperse Carbon Nanotubes in Poly(2,6‐Dimethyl‐1,4‐Phenylene Ether)/Polystyrene Blends

Cited by 4 publications

References 37 publications

Bimodal Latex Effect on Spin-Coated Thin Conductive Polymer–Single-Walled Carbon Nanotube Layers

Bimodal Latex Effect on Spin-Coated Thin Conductive Polymer–Single-Walled Carbon Nanotube Layers

Latex Technology for Conductive Polymer Nanocomposites

Physical Properties of Hydrogen‐Bonded Polymers

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