Light-weighting of vehicle is now strongly required for reducing gasoline consumption and CO₂ emission. Previously, we have been found that the surface of silicone rubber was photo-chemically modified into carbon-free silica (SiO₂) by irradiation of a 157 nm F₂ laser. We switched silicone rubber to silicone resin-for advanced coating applications and have focused on whether the resin can be modified into SiO₂ as same as the case in the rubber. In this study, F₂ laser was irradiated to the surface of hard silicone resin. The silicone resin was coated by dip coating method onto the film of acrylic resin on a polycarbonate substrate. The thickness of silicone resin was about 4 µm. The surface part of the silicone resin was modified to SiO₂, maximum thickness was approximately 1.3µm. One of two types of aperture mask, 3×3 mm² and 50×50 µm², was set on the sample surface. The single pulse fluence was varied from 4 to 14 mJ/cm², pulse repetition frequency was set to 10 Hz, and irradiation time was changed from 30 to 120 s. N₂ gas was induced around the surface of the sample. Then the SiO₂ modified layer of samples were etched by HF 1% diluted solution. After etching, the etched depth was measured by a stylus-type surface profilometer.
The results of above experiments, it was found that the tensile stress in the SiO₂ modified layer increased by increasing of F₂ laser irradiation time. In the case of using aperture mask of 3×3 mm², cracks were generated only on the irradiated area for longer irradiation time than 60 s. It is considered that the tensile stress in the modified layer exceeds the tensile fracture strength of 48MPa of typical SiO₂. When a mesh mask of 50×50 µm² was used, no crack generates on the irradiated areas even for a long irradiation of 200 s. The volumetric shrinkage might cause a tensile stress in the SiO₂ modified layer and its thickness reduction works to release the strain in the lateral direction. We estimated the tensile stress by calculation. The result of considerations, we found that the tensile stress can be reduced remarkably by using smaller aperture size of mesh mask, and it is very effective to prevent cracking. On the basis of zoning the laser-irradiated area in micron size, the thicker film of SiO₂ 1µm and over was successfully formed without cracking.