Due to a lack of lattice-matched substrates, III-nitride devices can only use heteroepitaxy and materials with different lattice constants as the substrate, resulting in a high defect density. Furthermore, differences in thermal expansion coefficients induce bowing or even crack of the crystal. These problems do not affect devices with low current density (such as LEDs); however, they significantly influence devices with high current density (such as blue LD) and high power or the UV devices. Using the single-crystal III-nitride substrate for homoepitaxy can not only reduce the high defect density due to mismatched lattice constants and crystal bowing caused by the different thermal expansion coefficient, but can also simplify the device fabricating procedures and improve the reliability of the devices. The use of single-crystal III-nitride substrates is certain to impact the optoelectronic devices development in the future. This thesis focuses primarily on the growth of GaN thick films using hydride vapor phase epitaxy (HVPE). However, overcoming the crystal crack caused by the thermal strain of the different thermal expansion coefficients remains the substantial problem to be solved. The researchers adopted GaN nanorods as the growth template to overcome strain problems and reduce the defect density and remaining strain inside GaN thick films through sidewall lateral epitaxial overgrowth (SLEO). After the GaN thick films grow on HVPE, the different thermal expansion coefficients between the sapphire substrate and GaN thick films generates strain when the temperature cooling down of the HVPE system. Due to the nanorods very weak, GaN nanorods are broken by the strain. GaN thick films are thus separated from the sapphire substrates, becoming freestanding GaN substrates. This study employed SEM, CL, PL, Raman, and HRXRD to measure the properties of GaN substrates. The threading dislocation of GaN substrates is approximately 107 cm-2 with a 196 aresec FWHM of the X-ray rocking curve. The Raman, PL, and CL spectrum analysis indicated that the strain inside freestanding GaN substrates was almost released. The test results demonstrated that after GaN thick films were separated from the substrate, the quality of the lattice improved significantly; the strain was released and the entire film became unstrained. The researchers compared LEDs grown on FS-GaN and sapphire substrates to test the optoelectronic characteristics of LEDs on different substrates. For InGaN/GaN multiple quantum well light-emitting diodes (LEDs) grown on the FS-GaN substrates, the defect densities in the homoepitaxially grown LEDs were substantially reduced, leading to improved light emission efficiency. Compared with LEDs grown on sapphire, this study obtained a lower forward voltage, smaller diode ideality factor, and higher light output power in the same structure grown on FS-GaN. The external quantum efficiency (EQE) of LEDs grown on FS-GaN was improved, particularly at high injection currents, significantly reducing the efficiency droop phenomenon at high current density.