In recent years, thermoelectric energy has become more popular due to the fact that we are constantly searching for new solutions to solve the looming energy crisis. To determine the heat conversion efficiency of a material, one must measure its figure of merit (ZT value). In general, a higher ZT value would mean greater efficiency of turning heat into electricity. Electrical conductivity, thermal conductivity and Seebeck coefficient are much related to ZT value. Among various thermoelectric materials, semiconductors are the most popular materials that are constantly studied due to their better ZT values. Recently, the conducting polymer, Poly(3-hexylthiophene) (P3HT), has been extensively studied because of its unique thermal and electrical properties. The band gap of P3HT is about 1.9 eV, which is in the same the band gap range of typical semiconductors. By making the P3HT into nanowires, we expects to lower the thermal conductivity of the nanowires due to the reduced dimensionality and to improve their ZT values. We successfully determined an electrical conductivity of 3.3x10-7 1/ohm from single P3HT nanowires. The value of the electrical conductivity remained stable even after wires were exposed in ambient for weeks. In addition, we fabricated “T-type” devices by using PECVD, E-beam lithography, E-gun evaporation and wet-etch to measure the thermal conductivity of single P3HT nanowires. We extracted a thermal conductivity of 0.0552 (W/mK) from a single P3HT nanowire.