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RESEARCH PRODUCT
Controlling electrical percolation in multicomponent carbon nanotube dispersions
Ce Cor KoningAv Andriy KyrylyukAv Andriy KyrylyukTanja SchillingTanja SchillingL Bert KlumpermanPpam Paul Van Der SchootPpam Paul Van Der SchootMc Marie Claire Hermantsubject
NanotubeMaterials scienceLatexPolymersSurface PropertiesCarbon nanotube actuatorsBiomedical EngineeringBioengineeringCarbon nanotubelaw.inventionNanocompositesElectricitylawNanotechnologyGeneral Materials ScienceElectrical and Electronic EngineeringComposite materialParticle SizeNanotubes CarbonElectric ConductivityPercolation thresholdCondensed Matter PhysicsAtomic and Molecular Physics and OpticsCarbon nanotube metal matrix compositesOptical properties of carbon nanotubesPercolationDispersion (chemistry)Monte Carlo Methoddescription
Carbon nanotube reinforced polymeric composites can have favourable electrical properties, which make them useful for applications such as flat-panel displays and photovoltaic devices. However, using aqueous dispersions to fabricate composites with specific physical properties requires that the processing of the nanotube dispersion be understood and controlled while in the liquid phase. Here, using a combination of experiment and theory, we study the electrical percolation of carbon nanotubes introduced into a polymer matrix, and show that the percolation threshold can be substantially lowered by adding small quantities of a conductive polymer latex. Mixing colloidal particles of different sizes and shapes (in this case, spherical latex particles and rod-like nanotubes) introduces competing length scales that can strongly influence the formation of the system-spanning networks that are needed to produce electrically conductive composites. Interplay between the different species in the dispersions leads to synergetic or antagonistic percolation, depending on the ease of charge transport between the various conductive components.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-01-01 |