Abstract
Effects of various experimental parameters on dc conductivity of Silicone-Carbon Black (CB) nanocomposites are measured and correlated to the fractal morphology of CB network. The influence of filler volume fraction, temperature and electric field strength, are discussed using percolation and variable range hopping on a fractal as theoretical background. One also investigates effects of curing rate and CB content on both surface?s morphology and conductivity. The fractal aspect of CB network is studied by optical microscopy (OM). Electric conductivity is measured using four points setup. AFM and STM are used to study respectively surface morphology and conductivity. Low percolation threshold c;=;0,15% and scaling exponent ?;?;2,6 of conductivity with CB volume fraction is correlated to the measured fractal dimension d(f);=;2,4. Conduction at low temperature proceeds by mean of variable range hopping on the CB fractal network with a Mott?s exponent m;=;0,65 and temperature T-0;=;64 K. Non-Ohmic conductivity curves at different temperatures could be superposed into a unique master curve and the onset field of non-linearity Scales with temperature with a typical exponent X-T;?;1,2. At low curing rate, capillary forces have time to bring down all CB particles from the surface into the bulk whereas at fast curing rate the roughness and conductivity of the surface remain high.