Skip to main content
Article
Behavior of Na+-Polystyrene Sulfonate at the Interface with Single-Walled Carbon Nanotubes (SWNTs) and Its Implication to SWNT Suspension Stability
Polymers
  • Tabbetha A. Dobbins, Rowan University
  • Richard Chevious
  • Yuri Lvov
Document Type
Article
Version Deposited
Published Version
Publication Date
6-14-2011
DOI
http://dx.doi.org/10.3390/polym3020942
Abstract

The assembly of sodium polystyrene sulfonate (Na+-PSS) at the surface of single-walled carbon nanotubes (SWNTs) in pH 3 aqueous solution is described. Rather than forming linear or sheet-like chain morphologies over SWNT surfaces, Na+-PSS adopts a spherically collapsed conformation believed to be the result of cation (either Na+ or H+) condensation onto the ionized polymer chain. It is well reported that cations (and also anions) adsorb preferentially onto single-walled and multi-walled carbon nanotube surfaces leading to an increased ion concentration in the near surface regions relative to the bulk solution. This work provides experimental evidence for preferentially absorbed cation condensation onto PSS anions until those cations are spaced at distances corresponding to the Bjerrum length ( B), as defined by the Manning theory of ion condensation, at the SWNT surface. The resulting electrostearic repulsions allow the SWNTs to remain suspended for days. Furthermore, coulombic repulsion among SWNT bundles after cation adsorption alone is not sufficient to form stable suspensions—but rather the stearic repulsions associated with spherically collapsed PSS at the nanotube surface is responsible for suspension stability. It is believed that the ultrasonic agitation drives cations into the small spaces between SWNT bundles and coulombic potential attracts the PSS to those regions.

Creative Commons License
Creative Commons Attribution 4.0 International
Citation Information

Dobbins, T., Chevious, R., & Lvov, Y. (2011). Behavior of na +-polystyrene sulfonate at the interface with single-walled carbon nanotubes (SWNTs) and its implication to swnt suspension stability. Polymers, 3(2), 942-954.