Nano- and Microcomposites for Electrical Engineering Applications

© 2014 MDPI; under CC BY-NC-ND license

poly(2-oxazoline)s; crosslinked polymers; thiol-ene click chemistry; permittivity; loss factor; interfacial polarization; electrical conductivity; dielectric properties; inorganic–organic nanocomposite; surface hydroxylation; energy storage density; fuel cells; nafion nano-composite membranes; sulfated titanium dioxide; structural (XRD); thermal (TGA) and morphological (TEM) characterization; vibrational spectroscopy; FT-IR absorption and ATR spectroscopy; micro-Raman spectroscopy; low-density polyethylene; nanocomposites; dc conductivity; charge carrier mobility; charge transport; trap depth; low-density polyethylene; nanocomposites; charge transport; dc conductivity; charge injection; trapping; de-trapping; charge carrier mobility; graphene; carboxymethyl chitosan; sensor; differential pulse anodic stripping voltammetry; Cu(II); nanoparticle; surface functionalization; nanocomposite; morphology; dielectric breakdown strength; dielectric relaxation; in situ-formed silver nanoparticles; silver nanowire; epoxy resin; nanocomposite; micro/nanocomposites; electrical properties; mechanical properties; thermal properties; high-voltage applications; cross-linked polyethylene; epoxy resins; numerical and analytical models; polymer/filler interface; mica; mica/epoxy-composites; insulation materials; failure mechanisms; electrical insulation; dynamic mechanical analysis; tensile; bending; impact behavior; thermosets; epoxy resin; nanocomposites; high-voltage engineering; mica/epoxy composites; crosslinked polyethylene (XLPE); mechanical properties; charge transport; surface chemistry