In this dissertation, two topics are included. One is planar GaN-based PIN UV photodetector, the other is the growth of InN film for high-efficiency photovoltaic matreial. Related to planar GaN-based PIN UV photodetector, first of all, the electrical and optical characteristics of GaN after Si ion implantation and subsequently thermal annealing were studied. Via Si ion implantation, p-type GaN can be converted to n-- or n+-type by proper implanting concentration and annealing conditions. Based on these results, an implanted GaN PIN UV photodetector with a planar geometry is able to be achieved. The dark current and responsivity between a conventional (with vertical structure) and a planar PIN UV photodetector were compared then. High-frequency response of the implanted GaN-based PIN UV photodetectors is one of the topics for this project. For increasing the quantum efficiency, large absorption layer should be realized to accept more incident photos. Therefore, it should be compromised between speed of carrier transport and quantum efficiency. Finally, the related material characterizations and device physics will be studied systematically. Related to the growth of InN film for high-efficiency photovoltaic material, among these semiconductors, quantum-dot sensitized TiO2 nanoparticles have been well-examined and showed the evidence of electron transfer from the quantum dots into the TiO2. Indium nitride is another candidate for this type of semiconductor-sensitized TiO2 system. InN, a well-characterized III-V semiconductor with a stable wurtzite crystal structure, has been used for visible optoelectronics and high-efficiency solar cell applications. This chemically stable and robust InN has a useful range of band gaps, 0.7~2.1 eV, which result from the crystallinity and quantum confinement effects.