By the formulation design of materials, nano-dispersion technique, control in shear flow field, design in stretch flow field, surface modification with functional groups, addition of the compatibilizers, development of T-Die, design of screw, and extrusion molding technique, optical films with high gas resistance, anti-static capability, and excellent physical properties (transparency≧ 90%, water vapor transmittance rate < 10 g/m2/day, oxygen transmittance rate (OTR) <150 (c.c./m2/day/atm.), anti-static capability: 109 - 1010 Ω/□, and film roughness: ±3%) have been prepared. With lab-made optical films, the lifetimes of flexible optoelectronic devices can be prolonged and the static problem for lamination of optical films during the scale-up of panels. Compared to the present procedures and materials such as addition of anti-static instruments and lamination of anti-static films, lab-made optical films were superior, being capable to assist the domestic makers to enter into the market of optical films.