Full Text: IntroductionParticulate-

Full Text:

Introduction

Particulate-reinforced epoxy composites are widely used for applications in various engineering fields such as for packaging materials in electronic devices and components of aircraft and automotive, because of their excellent mechanical and insulation properties. Fracture toughness is one of the most important mechanical properties of materials to improve the reliability of these devices and components. By diminishing the particle size from the micrometer to the nanometer level, nanocomposites are produced to further improve mechanical properties.

The fracture properties of silica particulate-reinforced epoxy composites have been investigated in several previous studies. Several researchers have conducted intensive studies regarding the effects of particle volume fraction and its size on the properties of micro- or nano-silica particulate-reinforced epoxy composites. Spanoudakis and Young [1, 2], Moloney et al. [3], Nakamura et al. [4, 5], and Adachi et al. [6] reported that fracture properties strongly depended on particle size, shape, and volume contributing to the differences in crack propagation and interaction of particles with matrixes. Preghenella et al. [7], Kitey et al. [8], Butcher et al. [9], Kwon et al. [10-15], and Adachi et al. [16-18] clarified that the fracture properties strongly related to the size distributions of silica particles due to enhanced interactions between the particles and the matrixes. Rapid interparticle distance with decreasing particle size resulted in more interactions between particles and epoxy matrixes. The interfacial interaction of particles with the surrounding matrix is closely related with the cross-linking network morphology in polymer matrixes [19-21]. Therefore, the fracture properties of nano- or micro-particle-reinforced epoxy composites are considerably dependent not only on the particle size effect but also on the internal network structures of the epoxy matrixes.