Block copolymers have stimulated significant scientific interest since they offer the possibilities to nanoscale materials with tunable morphology and properties. In this thesis, linear diblock copolymer polystyrene-block-poly(2-vinyl pyridine) (L-PS-b-P2VP), heteroarm star copolymer H-PS-b-P2VP, and blockarm star copolymer B-PS-b-P2VP, were successfully synthesized by living anionic polymerization. Then, the different architectures of the PS-b-P2VP were used to prepare two different types of self-assembled nanostructures: (1) block copolymer-amphiphile complexes (PS-b-P2VP/DBSA); (2) mesoporous methylsilsesquioxane (MSSQ) materials using PS-b-P2VP as templates. The experimental results showed that intermolecular bonding existed between the nitrogen of the 2-VP ring and the HSO3 or DBSA. Thus, the hierarchical self-organized supramolecules were obtained from the PS-b-P2VP/DBSA complexes. All the PSP2VP copolymers with a similar composition and molecular weight have lamellar morphology in the neat state. On complexation with the DBSA, the SAXS profiles suggests the formation of the hierarchical structures consisted of hexagonally packed PS cylinders in the P2VP(DBSA) lamellar morphology at a high temperature. The interdomain distance in the H-PS-b-P2VP(DBSA) and L-PS-b-P2VP(DBSA) complexes does not change significantly as the morphology change from lamellae to cylinder by complexation, but that in the B-PS-b-P2VP(DBSA) complexes shows a significant decrease. Besides, the order-disorder transition also varies significantly in the complexes of different architectures. The B-PS-b-P2VP/DBSA complex has the lowest TODT whereas the H-PS-b-P2VP/DBSA complex has the highest TODT, which is probably due to the difference on the polymer architecture. The central cores in blockarm and heteroarm block copolymers are located inside the microdomain and at the interface, respectively, which results in different degree of non-gaussian chain stretching in these copolymers. In the second topic of the thesis, nanoporous MSSQ films were prepared through the templating of PS-b-P2VP using the processes of evaporation-induced self-assembly dry-casting (for bulk materials) and dip-coating(for thin film). Hydrogen-bonding and ionic bonding interaction between the MSSQ precursors and PSP2VP prevents large-scale phase-separation before thermal treatment. Upon thermal curing, the self-condensation between the MSSQ end group results in the microphase separation between the MSSQ and PSP2VP. The self-organized PSP2VP was removed by thermal curing and left nano-pores in the MSSQ matrix. Morphologies of bulk materials were characterized preferentially using SAXS and TEM. Ordered porous thin films were observed from the images of the FE-SEM, TEM, and AFM. The pore size prepared from the cases of the MSSQ/L-PS-b-P2VP or H-PS-P2VP are in the range of 17 to 22 nm, depending on the PS-b-P2VP loading (30% ~ 50%). However, the MSSQ/B-PS-b-P2VP results in small discrete pores to connected metamorphic pores at polymer loading of 50 wt%, which could be due to the large polydispersity of the B-PS-b-P2VP. The experimental result in this thesis suggests that the architecture of the block copolymers plays a very important role on controlling the morphologies of the resulted nanostructured derivatives.