47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials
Conference
1 - 4 May 2006, Newport, Rhode Island
AIAA 2006-1678
Micromechanics Modeling of Functionally Graded
Interphase Regions in Carbon Nanotube-Polymer
Composites
Gary D. Seidel and Dimitris C. Lagoudas
Texas A&M University, College Station, TX, 77843-3141, USA
Sarah Jane V. Frankland
National Institute of Aerospace, Hampton, VA, 23666-1399, USA
Thomas S. Gates
NASA Langley Research Center, Hampton, VA, 23681, USA
The effective elastic properties of a unidirectional carbon fiber/epoxy lamina
in which
the carbon fibers are coated with single-walled carbon nanotubes are modeled
herein
through the use of a multi-scale method involving the molecular dynamics/equivalent
continuum
and micromechanics methods. The specific lamina representative volume element
studied consists of a carbon fiber surrounded by a region of epoxy containing
a radially
varying concentration of carbon nanotubes which is then embedded in the pure
epoxy
matrix. The variable concentration of carbon nanotubes surrounding the carbon
fiber
results in a functionally graded interphase region as the properties of the
interphase region
vary according to the carbon nanotube volume fraction. Molecular dynamics and
equivalent continuum methods are used to assess the local effective properties
of the carbon
nanotube/epoxy comprising the interphase region. Micromechanics in the form
of
the Mori-Tanaka method are then applied to obtain the global effective properties
of the
graded interphase region wherein the carbon nanotubes are randomly oriented.
Finally,
the multi-layer composite cylinders micromechanics approach is used to obtain
the effective
lamina properties from the lamina representative volume element. It was found
that
even very small quantities of carbon nanotubes (0.36% of lamina by volume) coating
the
surface of the carbon fibers in the lamina can have a significant effect (8%
increase) on
the transverse properties of the lamina (E22, v23, G23 and G12) with almost
no affect on the
lamina properties in the fiber direction (E11 and v12).