Thermoelectric Properties of Poly(3-hexylthiophene) Nanofiber Aerogels with a Giant Seebeck Coefficient

Aerogels comprising poly(3-hexylthiophene) (P3HT) nano-fibers dispersed in polystyrene (PS) were fabricated by freeze-drying, doped with iodine vapor, and subjected to thermoelectric property analysis, which revealed that the aerogel structure facilitated quite low thermal conductivity for temperature gradient preservation, while the P3HT nanofiber network percolating the aerogel bulk acted as an effective conductive structure. The highest Seebeck coefficient (S) of >10 mV K-1 was observed at a P3HT/PS mass ratio of 6:94. At low dopant concentrations (i.e., sigma < 10(-5) S cm(-1)), the relationship between S and conductivity (sigma) followed that of nondegenerate polymer semiconductors (S similar to sigma(-1/4)), while at high dopant concentrations (sigma 10(-5) S cm(-1)), the S-sigma relationship followed that of metals or degenerate semiconductors (S similar to sigma(-1)), and cross-over behavior was observed. The giant Seebeck coefficient was ascribed to the unique morphology of the freeze-dried aerogel and the effect of energy filtering. A foam-based energy harvester comprising the P3HT nanofiber aerogel was demonstrated, and a significant induced voltage using a single cell indicated the advantage of P3HT nanofiber aerogels with the giant Seebeck coefficient.

Automated summary

Aerogels containing P3HT nanofibers in a PS matrix were fabricated by freeze-drying and doped with iodine vapor. The aerogels exhibited low thermal conductivity and high Seebeck coefficient, showing potential for thermoelectric applications. The relationship between Seebeck coefficient and conductivity varied at different dopant concentrations, with a giant Seebeck coefficient attributed to unique morphology and energy filtering effects.