چکیده
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Reverse nonequilibrium molecular dynamics simulations were done to quantify the effect
of the inclusion of carbon nanotubes (CNTs) in the Polyamide-6,6 matrix on the enhancement in
the thermal conductivity of polymer. Two types of systems were simulated; systems in which
polymer chains were in contact with a single CNT, and those in which polymer chains were in
contact with four CNTs, linked together via polymer linkers at different linkage fractions. In both
cases, heat transfer in both perpendicular and parallel (to the CNT axis) directions were studied.
To examine the effect of surface curvature (area) on the heat transfer between CNT and polymer,
systems containing CNTs of various diameters were simulated. We found a large interfacial thermal
resistance at the CNT-polymer boundary. The interfacial thermal resistance depends on the surface
area of the CNT (lower resistances were seen at the interface of flatter CNTs) and is reduced by
linking CNTs together via polymer chains, with the magnitude of the reduction depending on the
linkage fraction. The thermal conductivity of polymer in the perpendicular direction depends on the
surface proximity; it is lower at closer distances to the CNT surface and converges to the bulk value at
distances as large as 2 nm. The chains at the interface of CNT conduct heat more in the parallel than
in the perpendicular directions. The magnitude of this thermal conductivity anisotropy reduces with
decreasing the CNT diameter and increasing the linkage fraction. Finally, microscopic parameters
obtained from simulations were used to investigate macroscopic thermal conductivities of polymer
nanocomposites within the framework of effective medium approximation.
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