Development of epoxy or epoxy-based vinyl ester composites with improved mechanical and electromagnetic properties, filled with carbon-based nanomaterials, is of crucial interest for use in aerospace applications as radar absorbing materials at radio frequency. Numerous studies have highlighted the fact that the effective functional properties of this class of polymer composites are strongly dependent on the production process, which affects the dispersion of the nanofiller in the polymer matrix and the formation of micro-sized aggregations, degrading the final properties of the composite. The assessment of the presence of nanofiller aggregation in a composite through microscopy investigations is quite inefficient in the case of large scale applications, and in general provides local information about the aggregation state of the nanofiller rather than an effective representation of the degradation of the functional properties of the composite due to the presence of the aggregates. In this paper, we investigate the mechanical, electrical, and electromagnetic properties of thermosetting polymer composites filled with graphene nanoplatelets (GNPs). Moreover, we propose a novel approach based on measurements of the dielectric permittivity of the composite in the 8-12 GHz range in order to assess the presence of nanofiller aggregates and to estimate their average size and dimensions.
Crazes constitute one of the most
common failure mechanisms in
polymers. They act as fracture precursors, severely degrading the
mechanical properties of the material. Thus, a deep understanding
of the chain rearrangement occurring inside crazes is of utmost fundamental
and practical importance. We have employed synchrotron infrared microspectroscopy
(SIRMS) and Raman microspectroscopy to investigate the conformational
changes inside micron-sized crazes in poly(ethylene terephthalate),
PET. A promotion of the full-extended chain conformational structure
at the expense of mainly the trans amorphous mesomorphic
phase along with an increase in crystallinity of around 4% has been
found. These results differ from what we observed across the deformation
neck during PET cold drawing, where no promotion of the all-trans crystalline conformation occurred for slow
drawing speeds at temperatures well below the glass transition. Our
results show the tremendous capabilities of advanced vibrational microspectroscopy
techniques to investigate microscale phenomena in polymer science.
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