This paper reports results on the electrical properties of laminated epoxy composite containing 25 layers of carbon fibers in the form of mats. The dependence of the activation energy (calculated from DC resistivity measurements) on temperature reveals two independent conduction processes. The AC impedance is independent of the applied frequency below 75°C, and the real componet of the dielectric constant is also independent of temperature at high frequencies. The determined shielding effectiveness is dominated by the insertion loss. The observed optimum shielding effectiveness occurs at 30 mm spacing and applied frequency 9 GHz.
This work deals with the effect of temperature on the electrical properties of laminated epoxy composites containing 60% by volume of commercial unidirectional carbon fibers. The temperature was varied from 30°C to 120°C and the frequency range was from 10 Hz to 10 kHz. It is found that the impedance decreases with increasing temperature and is inversely proportional to the number of layers in the specimen. The calculated dielectric constants show a strong dependence on the frequency below 100 Hz, and attain relatively constant values for frequencies greater than 100 Hz. The decrease in impedance with increasing number of layers was explained in terms of the existence of electrical contacts and bridges both between and within the fibers, in the carbon fiber layers. The activation energy results indicate that there are two conduction mechanisms in this laminated composite.
The optical and electrical characteristics of prepared poly(ethylene oxide)/alum composites are studied as a function of alum content and frequency. The optical energy band gaps were determined from the measured absorption spectra. The frequency of the applied electric field and alum content affect the dielectric behavior and the AC electrical conductivity of the prepared solid thin films. Correlation between the observed optical energy gaps and the AC electrical conductivity is presented. Generally, the observed enhancement in the electrical quantities is attributed to impurity, and ionic interactions take place in the bulk of the double electrolyte solid solution.
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