In this thesis, we use the effective synthetic approach (Surface-initiated vapor deposition-polymerization (SI-VDP)) to fabricate surface-grafted polypeptides on silicon, quartz, and Au surface for further applications. Firstly, biomimetic porous silica films have been synthesized by polycondensation of tetraethoxysilane on a soft template formed by “end-tethered poly(L-lysine)” (“t-PLL”) monolayer with a brush-like configuration. The silica formation occurs spontaneously inside the t-PLL at neutral pH and room temperature. The growth of silica fully conforms to the original t-PLL film thicknesses and lateral micro-patterns, regardless of prolonged reaction time and monomer concentration. The morphologies of biomimetic silica are changed from continuous pleated, discrete spherical, to fibrous forms according to the initial t-PLL chain length and surface density. After burning off the t-PLL template, TEM images show the creation of nano-channel arrays in silica with average diameter of 10 nm. Overall, our approach has provided a straightforward and environmentally friendly route to directly generate silica films with controllable morphology, thickness and porosity. Secondly, Polypeptide based molecular diode with high rectification ratio (~ 122 at ±0.422V) is formed by controlling molecular order and orientation. A film of tethered poly(γ-benzyl-L-glutamate) (PBLG) with high degree of molecular orientation was formed by solvent pair (good/bad) treatment. I-V characterization of the well aligned polypeptides showed that the rectification ratio of PBLG was sufficiently large for potential diode and transistor applications.