In this work, two nano carbon composites have been prepared and characterized. Conjugated polymers were used as dispersing agents for preparing single-walled carbon nanotubes (SWCNTs) solutions in organic solvents. It is found that the dispersion results of nanotubes are affected greatly by the polymer structure and solvent. With more flexible polymer backbone structure, more nanotube species can be observed by photoluminescence. That is, less selectivity this polymer behaves. Among three solvents we investigated, chloroform though gave the highest solubility, the evidences show that most of dispersed nanotubes remain bundles, which is unwanted. THF gave the second highest and toluene the lowest. However, the low solubility enhances the chance of selectivity. A strong chiral angle preference in favor of armchair structure has been observed in PFO/toluene solutions and diameter preference around 1.05 nm is obtained when PFO is replaced with PFO-BT. These results suggest the possibility for bulk purification of SWCNTs by using designated polymer/solvent combinations. The second composite, carbon-supported platinum (Pt) is aiming for fuel cell applications, in which the carbon materials were fabricated by polymer blend method and Pt nanoparticles were loaded with ion-exchange technique. Porous properties of carbon supports are found to be dependent on the carbonization conditions and mixed-polymers’ ration and a carbon support with mesoporous structure and surface area up to 441 m2/g is obtained; the dispersion and loading amount of deposited Pt are related to the Pt precursors and the surface acidity of carbon supports. An uniform particle size distribution around 2~4 nm and a loading amount of 16 wt% with exchange efficiency as high as 82% were achieved by this method, which is of sufficient requirements for fuel cells. Besides, the zeta potential curve can also be used to monitor the suitable pH region for ion-exchange reactions and to predict the loading amount of catalyst.