In this thesis, a-plane InGaN/GaN multiple quantum wells with different widths from 3 to 12 nm were grown on r-plane sapphire by metal organic chemical vapor deposition for investigation. We utilized photoluminescence (PL) technique to investigate the optical characteristics of our samples. The PL experiments revealed that the PL emission intensity would decrease with increasing the well width of the samples from 3 to 12 nm. Meanwhile, the power dependent PL measurement indicated no apparent emission peak shift for all samples due to no built-in electric field in a-plane MQWs. Moreover, the temperature dependent PL reveals that a more apparent localization effect exist in the sample with a thicker well width which is most likely due to more serious indium fluctuations or worse crystalline quality in the MQWs. In-plane polarization effect of a-plane InGaN/GaN MQWs emission was also investigated, which pointed out an average polarization degree ρ from our samples is about 60%. Furthermore, we have successfully grown a-plane green light-emitting diodes on r-plane sapphire and investigated the device characteristics of a-plane green LEDs. The apparent emission polarization anisotropy was observed and the polarization degree was as high as 67.4%. In addition, the electroluminescence (EL) spectra first revealed a wavelength blue-shift with increasing drive current to 20 mA, which could be attributed to the band-filling effect, and then the EL peak become constant. The current–voltage curve showed the forward voltage of a-plane LED grown on r-plane sapphire substrate was 3.43 V and the differential series resistance was measured to be about 24  as 20-mA injected current. Furthermore, the output power was 240 W at 100-mA drive current. These results should provide a useful guidance for fabrication of light emitting devices using a-plane InGaN/GaN MQW structures.