In this study, the ultra-thin TiO2 films were coated onto the highly porous silica to from bone-skin-like photocatalysts with controllable film thickness and high photoactivity by the combination of templating sol-gel method and surface sol-gel method. Monodispersive polystyrene microspheres in this study were prepared by emulsion polymerization method with sodium dodecyl sulfate (SDS) as stabilizer. The optimal condition to synthesis monodisperse polystyrene is reacting at 80 ℃ in preheated procedure when 1 CMC of SDS was added. The resulting monodisperse polystyrene microspheres with diameter about 190 nm were used as templates to fabricate the porous framework by infilling sol-gel derived silica into the voids between microspheres. The porous silica framework (bone structure) with ordered hexagonal porous structures in three dimensions was obtained by subsequently removing microspheres with calcinations. The ultra-thin TiO2 layers obtained from the surface sol-gel method was then coated on the surface of the porous silica framework to form the bone-skin-like structures. Results showed that the developed bone-skin-like porous photocatalyst has high surface area (410.5 ~ 534.9 m2/g) and retains quantum properties to perform the novelty on high specific photocatalytic activities (2.9 ? 10-2 ~ 3.6 ? 10-2 min-1mg-1). The thickness of the sol-gel-derived TiO2 thin films ranged from 4.6 to 9.4 nm can be well-controlled by simply adjusting the concentrations of the TiO2 precursors in the surface sol-gel process, while the photoactivity of the photocatalysts is highly dependent on the thicknesses of the ultra-thin TiO2 coatings. The bone-skin-like SiO2/TiO2 with the precursor concentration of 0.2 had the highest specific photocatalytic activity due to the highest surface area and short charge diffusion length. The relationship between degradation rate and physicochemical properties of photocatalysts was also discussed in this study.