Epoxy resin (ER)/graphite nanosheet (GN) composites with a low percolation threshold (owing to particular geometry of GN with the high aspect ratio) were fabricated. The nonlinear conduction behavior of ER/GN composites above the percolation threshold by the action of variable DC electrical field was investigated. For specimens, the current density or current reduces with decreasing graphite nanosheets concentrations, and the J-E curves are well fitted by a cubic, J = sigma E-1 + sigma E-3(3). Moreover, the crossover current density J(c), at which nonlinearity takes place, scales with the linear conductivity sigma(1) as J(c)similar to sigma(x)(1), with x approximate to 1.390 and the third-order conductivity, sigma(3), also scales with J(c) as J(c)similar to sigma(y)(3), with y approximate to 1.175. Through the discussion of the nonlinearity within the framework of two theoretical models, the nonlinear random resistor network (NLRRN) and the dynamic random resistor network (DRRN), it is indicated that neither of these two models can fully explain our experimental results. Taking into account the microscopic structures and conduction processes of the composites, it is likely that a combination of these two models explain the nonlinear characteristics better.

• 出版日期2007-11-15
• 单位华侨大学