Very fine alumina nanoparticles were loaded in novolac
type phenol-formaldehyde (PF) resin using solution
mixing method. The concentration of nanoalumina in
PF was varied between 2.5 to 20 wt%. All the compounds were compression molded and then subjected
to scanning electron microscopy (SEM), tensile, flexural, and dynamic mechanical analysis (DMA) tests.
SEM analysis showed that the nanoalumina particles
were dispersed uniformly at low concentrations, however, at high concentrations, dispersion was suppressed leading to agglomerates in the composites.
Mechanical testing revealed that the nanoalumina particles had a great influence on the strength and stiffness of PF resin particularly at concentrations below 5
wt%. However, at concentration above 5 wt%, the
stress concentrations were developed because of the
formation of big aggregates that results in strength
reduction. Theoretical analyses based on Pukanszky’s
model for tensile strength and micromechanical models for tensile modulus revealed that strong interfacial
interaction and thick interphase region around the alumina nanoparticles was formed. DMA results suggested that the nanoalumina increased the
crosslinking density of the PF resin, possibly around
the interface region. It was also postulated that an
apparent percolation state was established above 5
wt% loading of nanoalumina in which interphase
region came to contact before direct contact of particle leading to continuous interphase region. POLYM.
COMPOS., 35:1285–1293, 2014. VC 2013 Society of Plastics
Engineers