Abstract

In polymer nanocomposites, the interface region between the matrix and the fillers has been identified as a key interaction region that strongly determines the properties of the final material. Determining its structure is crucial from several points of view, from modeling (i.e., properties prediction) to materials science (i.e., understanding properties/structure relationships). In the presented paper, a method for characterizing the interface region of polymer nanocomposites is described using molecular dynamics (MD) simulations. In particular, the structure of the polymer within the interface region together with its dimension in terms of thickness were analyzed through density profiles. Epoxy resin nanocomposites based on diglycidyl ether of bisphenol A (DGEBA) were studied using this approach, and the interface region with triple walled carbon nanotubes (TWCNT) and carbon fibers (CF) was characterized. The effect of carbon nanotube diameter, type of hardener, and effect of epoxy resin cross-linking degree on interface thickness were analyzed using MD models. From this analysis no general rule on the effect of these parameters on the interface thickness could be established, since in some cases overlapping effects between the analyzed parameters were observed, and each specific case needs to be analyzed independently in detail. Results show that the diameter has an impact on interface thickness, but this effect is affected by the cross-linking degree of the epoxy resin. The type of hardener also has a certain influence on the interface thickness.

Highlights

  • Nanoparticle reinforced polymeric composites have generated considerable attention among material scientists and engineers due to their potential of producing superior physical, chemical, and mechanical properties

  • In the case of carbon nanotubes (CNT) composites cylindrical bins were defined around the central axis of the carbon nanotube, whereas in the case of CF composites rectangular cuboids bins were defined from the middle layer of the carbon fiber

  • Results defined around the central axis of the carbon nanotube, whereas in the case of CF composites rectangular cuboids bins were defined from the middle layer of the carbon fiber

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Summary

Introduction

Nanoparticle reinforced polymeric composites have generated considerable attention among material scientists and engineers due to their potential of producing superior physical, chemical, and mechanical properties. The interfacial interaction between polymer and nanoparticle manifests itself as perturbation of the structure (e.g., density, chain orientation or arrangement) and the dynamics of the polymer [4,5,6]. This region of altered polymer properties is commonly referred to in the literature as the interface. Carbon nanofillers, such as carbon nanotubes (CNT), graphene, and graphene nanoribbons (GNR), have attracted recent attention due to their extraordinary thermo-physical and electrical behavior [7]. The large surface area, Fibers 2018, 6, 54; doi:10.3390/fib6030054 www.mdpi.com/journal/fibers

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