In this thesis, the poly(3-thiophene-triazole-diaminopyridin) (PTDAP) possessing triple hydrogen bonding sites were successfully synthesized through chemical oxidative polymerization. Following blending with the biocompatible poly(4-vinylbenzyl uracil) (PVBU), nano/micro nanofibers can be fabricated through electrospinning. These results indicate that the presence of the hydrogen-bonding system may improve the morphology, thermal stability, functionality and compatibility of nanofibers for applying in carbon nanotube dispersion, biomatrix, filter, or battery seperation. In addition, we incorporate the multiwalled carbon nanotubes (MWCNTs) into the PVBU/PTDAP hydrogen-bonding system and successfully fabricated bead-free composite nanofibers with diameter down to 500 nm. Under the hydrogen-bonding system, the thermal stability of the composite nanofibers is improved apparently. Fourier transform Raman (FT-Raman) spectra, transmission electron microscope (TEM) and standard four probe result indicate that the conjugated polymer block such as polythiophenes can form strong non-covalent π–π interactions with multiwalled carbon nanotube walls which prevents MWCNTs from aggregating and dispersion, while the triple hydrogen-bonding interaction between PTDAP and PVBU provide the de-bundled MWCNTs with a good solubility and stability in the organic solvents and host polymer matrices. TEM observation showed the MWCNTs were parallel and oriented along the axes of the nanofibers which increase the conduction of electrons and therefore significantly enhance the conductivity.