In this study, we used P3HT as a template in-situ synthesizing titanium dioxide to manufacture an organic/inorganic nanohybrid system. This study reveals a simple in-situ method to manufacture a P3HT/TiO2 hybrid system. First, we made a P3HT/Ti4+ hybrid system by the formation of complextion via the intermolecular interaction between thiophene and titanium ions (Ti4+). To preserve TiO2 crystallizing in nanoscale, via the concept of chemical vapor deposition, we first let the solvent of P3HT/Ti4+ hybrid solution to evaporate to form a P3HT/Ti4+ hybrid thin film. Following, we used high pressure vapor containing H2O proceeding the in-situ sol-gel process to form a nanoscale amorphous TiO2, and then by the high pressure treatment, amorphous TiO2 crystallized to a nanoscale crystalline TiO2. We manufactured a P3HT/TiO2 nanohybrid system successfully. In the GIWAXS measurement, we found that many factors, containing the kinds of vapor conditions, reaction temperature and reaction time, affected the P3HT crystal structure, TiO2 crystal size, the transformation of TiO2 crystal structure and even the self-assembly. We can control the crystalline of TiO2 via finding out the influence of these parameters. In the 2D GIWAXS measurement, we provide a new concept: the hybrid system will proceed second self-assembly in the crystallization process. This attributed to the same concept with the mechanism of rutile formation in low temperature. In XPS measurement, we confirmed our assumption of intermolecular interaction between thiophene and titanium ions. The TEM profile reveals that the morphology of our hybrid system has good orientation to be a nanowire. Finally, via the UV-vis and PL analysis, we know the optical properties are good to be used in solar cells application.