The main target of this research is fabricating the bilayer transition metal dichalcogenides (TMDs) artificially, in which the effect of interlayer coupling was investigated by Raman and photoluminescence (PL) spectroscopy. In the first part, the effects of strain and charge doping in fabrication process were studied by the shifts of E2g and A1g phonon modes. We found the coupling of phonon mode is not directly correlated to the constitute materials, and the coupling will become as same as natural crystal if stacking another material. Furthermore, the interlayer electronic coupling was studied by PL spectroscopy. In homo-stacked MoS2/MoS2 bilayers, the clear Κ-Γ indirect PL demonstrates the electronic coupling is close to the bilayers formed in nature or grown by chemical vapor deposition (CVD). Most importantly, we observe the spatial reconstruction of twist angle into commensurate conditions, leading to the smooth evolution of indirect energy than CVD-grown twisted bilayers. In hetero-stacked MoS2/WSe2 bilayers, we observed a type-II K-K direct PL, demonstrating the type-II band alignment at the MoS2/WSe2 interface. The conduction and valence band offset were then determined by the PL measurements. In the last part, the crystal structures of CVD-grown monolayer and bilayer MoS2 were investigated by transmission electron microscopy (TEM). From the selected-area electron pattern, we found the triangle region is a single-crystal region with the Zigzag direction along the edge of triangle. Furthermore, the interlayer twist angle and atomic structure were studied by the high-resolution TEM image. Unlike the domination of 2H-bilayers formed in nature, we found the main stacking orders in CVD-grown bilayers are in 3R and 2H structures.