52nd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference
4 - 7 April 2011, Denver, Colorado

AIAA 2011-2058

Analysis of the Interface in CNT-Polyethylene Nanocomposites using a Multiscale Modeling Method

Yumeng Li and G.D. Seidel
Virginia Polytechnic Institute and State University, Blacksburg, VA, 24061-0203, USA

One anticipated application for carbon nanotube is as multifunctional reinforcement material in high performance nanocomposites and the structural composites in which nanocomposites may be embedded. The performance of the composites in terms of en- hanced mechanical, thermal and electrical properties is critically a ected by the interfacial characteristics between the CNTs and the polymer matrix. Hence, in order to design high performance CNT-polymer nanocomposites, it is essential to understand the interface of the CNTs and the polymer. As it is dicult to directly obtain the characteristics of the in- terface of CNTs and polymer through experiments, it is proposed to assess the interface be characterized using computational materials science approach. In the present work, force eld molecular dynamic simulation has been applied to assess the opening mode separation of the interface in nanocomposites at the nanoscale for a CNT-polyethylene nanocompos- ites. The peak force and the energy of separation are obtained by monitoring the force on a representative graphene layer as it is separated from a segment of the bulk polyethy- lene near the CNT interface, and subsequently used to construct cohesive zone parameters which can be transferred to higher level continuum model. In order to assess the suitable sizes for nanoscale representative volume elements(RVEs) to represent the real material system, several parameters such as the length of the polymer chain have been studied to discern their in uence on the measurements-peak force and energy of separation.Finally,the cohesive zones are applied within the framework of a generalized self-consistent compos- ite cylinder model in order to investigate the impact of the interface on the macroscale e ective properties of nanocomposites.