Title: A Micromechanics Model for the
Electrical Conductivity of Nanotube-Polymer Nanocomposites
Gary D. Seidel a, Dimitris C. Lagoudas
Department of Aerospace Engineering
Texas A&M University
College Station, TX 77843-3141
Journal of Composite Materials -- 2009 -- Volume 43,
Issue 9, pp. 917-941
Abstract
The introduction of carbon nanotubes into non-conducting polymers has
been
observed to yield orders of magnitude increases in conductivity at very
low concentrations
of carbon nanotubes. These low percolation concentrations have been
attributed
to both the formation of conductive networks of carbon nanotubes within
the polymer and to a nanoscale effect associated with the ability of
electrons to
transfer from one carbon nanotube to another known as electron hopping.
In the
present work a micromechanics model is developed to assess the impact
of the
effects of electron hopping and the formation of conductive networks on
the electrical
conductivity of carbon nanotube-polymer nanocomposites. The
micromechanics
model uses the composite cylinders model as a nanoscale representative
volume
element where the effects of electron hopping are introduced in the
form of a continuum
interphase layer, resulting in a distinct percolation concentration
associated
with electron hopping. Changes in the aspect ratio of the nanoscale
representative
volume element are used to reflect the changes in nanocomposite
conductivity associated
with the formation of conductive networks due to the formation of
nanotube
bundles. The model results are compared with experimental data in the
literature
for both single- and multi-walled carbon nanotube nanocomposites where
it is observed
that the model developed is able to qualitatively explain the relative
impact
of electron hopping and nanotube bundling on the nanocomposite
conductivity and
percolation concentrations.
Key words: A. Carbon Nanotube, B. Nanocomposite, C. Electrical
Conductivity,
D. Micromechanics, E. Composite Cylinders