Doping and temperature dependence of anisotropic conductivity in new polyacetylene

Abstract

The authors report on measurements of the conductivity of 'new' polyacetylene as a function of temperature for iodine and halide doping, for different dopant concentrations and for stretched and unstretched samples. The temperature dependence of conductivity in highly-doped stretched samples is remarkably similar parallel and perpendicular to the stretch direction, despite a difference in conductivity magnitudes by a factor of about 50. In particular, a maximum in the conductivity below room temperature (for AsF₅ doping) is seen for the first time in the perpendicular as well as the parallel direction. The temperature dependence of the conductivity for the highly-doped stretched samples is in good agreement with a model of quasi-one-dimensional conduction combined with fluctuation-induced tunnelling through thin 'barriers' (for example chain defects). For unstretched samples, a model involving tunnelling between metallic islands gives a better description of the data.