Abstract
In this work, we prepared and investigated two series of polymer composites, wherein the matrix was either an amorphous polystyrene (PS) or a semicrystalline high-density polyethylene (HDPE) filled with expandable graphite (EGr) at relatively high loadings within the range 5–55 wt %. For the investigation we employed a thermogravimetric analysis and differential scanning calorimetry to assess the thermal transitions and evaluate the various polymer fractions (crystalline (CF), mobile (MAF) and rigid amorphous (RAF)) in addition to broadband dielectric spectroscopy and a laser flash analysis to evaluate the EGr effects on electrical conductivity, σ, and thermal conductivity, λ, respectively. In PS, EGr was found to impose an increase of the glass transition temperature and a systematic decrease of the corresponding heat capacity change. The latter was rationalized in terms of the formation of an interfacial RAF. No glass transition was recorded for HDPE whereas the fillers increased the CF moderately. As expected, σ increased with the filler loading for both matrices, up to 10−3–10−2 S/cm, resulting in a conductive percolation threshold for electrons at > 8 wt % EGr. Simultaneously, the λ of PS and HDPE were strongly increased, from 0.13 and 0.38 W·K–1·m–1 up to 0.55 and ~2 W·K–1·m–1, respectively. λ demonstrated an almost linear EGr loading dependence whereas the semicrystalline composites exhibited a systematically higher λ.
Highlights
Over the last decades, polymer composites and nanocomposites (PNCs) [1,2] have been under extensive investigation and have found use in a wide range of applications from industry, biochemistry and biomedicine to our everyday life
We prepared, by simple melt-compounding, and investigated polymer composites consisting of amorphous PS or semicrystalline high-density polyethylene (HDPE) filled with 5–55 wt % expandable graphite (EGr)
Complementary techniques, Thermogravimetric Analysis (TGA), Differential Scanning Calorimetry (DSC)-temperature modulation in DSC (TMDSC), Broadband Dielectric Spectroscopy (BDS) and Laser Flash Analysis (LFA), were employed to explore the thermal transitions and evaluate the electrical and thermal conductivity. In both types of polymer in the amorphous state based on TGA data, polymer-EGr interfacial interactions seemed to be formed and, indirectly, led to hindered thermal decomposition
Summary
Polymer composites and nanocomposites (PNCs) [1,2] have been under extensive investigation and have found use in a wide range of applications from industry, biochemistry and biomedicine to our everyday life. The main benefits of PNCs compared with neat polymers and traditional macrocomposites are the improved properties and performance achieved at very low filler loadings [1,3,11]. This is due to the high surface to volume ratio of the fillers arising from their nanodimensions [12], which provides a large potential for interfacial interactions between the filler and the polymer. Importance has been considered within the performance of PNCs of the role of amorphous crystal interfaces (RAFcrystal) [22,31,32] due to their special structure following partly the lamellae ordering (Scheme 1a)
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