GaN-based optoelectronic devices can be used in a wide range of applications due to its wide band gap coverage (from ultraviolet to infrared), sustainability of high electrical field, and high temperature operation. In the last two decades, we saw a strong demand of GaN-based lasers or light emitting diodes (LEDs), which will eventually change our daily life. In this study, in order to achieve high efficiency LEDs and enhance crystal quality of epitaxial layer, we adapted three nano-scale technologies to prepare our substrate: native grown GaN nanopillar, embedded SiO2 nano-mask etched nanopillar, and Si-based nanopillar. In the first part of the thesis, we presented a novel design of high-performance LEDs using a GaN nanopillars (NPs) structure grown on sapphire substrate by integrating RF-plasma molecular beam epitaxy (MBE) and metal–organic chemical vapor deposition (MOCVD). The GaN NPs suppress the threading dislocations effectively by nanoscale epitaxial lateral overgrowth (NELOG). The LEDs fabricated on the GaN NPs template exhibit smaller electroluminescent peak wavelength blue shift and great enhancement of the light output (70% at 20 mA) compared with the conventional LEDs. We also successfully demonstrated high bright LEDs with embedded microscale air voids and SiO2 nanomask. It was found that the residual stress was reduced from 1.73 to 0.88 GPa in the GaN epitaxial layer by inserting the microscale air voids and SiO2 nanomask. On the other hand, we observed strong reflectance modulations due to the different refractive indices between the GaN and sapphire. In addition, the NR-LEDs shows large enhancement of the light output (65% at 20 mA) compared with the C-LEDs. Finally, we investigate the material, optical and electrical characteristics of the GaN-based LEDs grown on micro- and nano-scale patterned silicon substrate (MPLEDs and NPLEDs). From material measurement, it indicates that the crystalline quality of the epitaxial structure fabricated on NPSi substrate is superior to MPSi substrates. From optical measurement, NPLEDs have better carrier confinement and higher radiative recombination rate than MPLEDs. In terms of device performance, NPLEDs exhibit smaller electroluminescence peak wavelength blue shift, lower reverse leakage current and decrease in efficiency droop when compared with the MPLEDs. In this dissertation, we can achieve the studies on the growth of high crystal quality and fabrication high performance LEDs devices. We hope using novel nanotechnology to be effective for improving the quality of GaN-based optoelectronic devices in future.