Nanotechnology is the study, design, manipulation and application of matter in nanoscale. In recent years, the properties of materials in nanoscale have attracted great attention in different fields. In this thesis, we studied the optical behaviors and applications of materials surface within nanoscale region. The main topics of the thesis include designing different nanostructures for photocatalytic reaction and analysing the surface behaviors of silicon carbide in atomic scale. In the first part, we developed an interference effect based nanocavity structure which could efficiently enhance the absorption of gold nanoparticles and N-doped TiO2 on the cavity structures. The nanocavity based structure could be applied for enhancing visible light photocatalytic reaction. Ihe cavity would increase the absorption of incident light and could effectively generate electron-hole pairs on the structures. Therefore, the combination of N-TiO2, gold nanoparticles, and nanocavity structure could dramatically enhance the efficiency of visible light photocatalytic reactions. We further calculated the photocatalytic efficiency of per unit amount of photocatalyst, and compare the result with previous studies. The result demonstrated that the amount of photocatalyst used in this study is few, however, the photocatalytic efficiency is very high. In the second part of the thesis, we combined the optical and thermal effects from light source and applied that to enhance the photocayalytic reaction. By using a nano-stalactites structure, up to 95% of the incident light could be absorbed and further converted to heat. Therefore the N-TiO2 on nanostructures could quickly react with methylene blue under visible light by photothermal-catalytic reaction. We found the reaction rate of the N-TiO2 on nanostructure was much higher than the commerical P25 TiO2 nanoparticles based samples. In the last part, we used non-destructive optical analysis methods including Raman scattering spectroscopy and visible-IR spectroscopy to analysis the surface properties of silicon carbide within nanoscale. The analyses included the polytypes, carries concentrations, impurities, micropipes and surface polarity of silicon carbide. By combining laser with different object lenses, the position of micropipes could be determined. In this study, we found the characterization surface polarity of silicon carbide could be conducted by attenuated power of Raman laser. With reduced power of Raman laser, the penetration depth could be effectively decreased, and the Raman signal contributed by surface region of SiC would be largely increased. By this method, we could successfully identify the silicon face or carbon face with atomic layer thickness on the surface of a silicon carbide wafer .