During the past decade, GaN-based materials, which provide wide direct bandgap and strong binding energy, have been drew great attention and widely used in various optoelectronic devices including light emitting diodes, laser diodes, photon-detectors and solar cells. For further manipulation of light characteristics and realization different function of high efficiency optoelectronic devices, photonic crystals (PCs) are a great candidate to achieve high efficiency optoelectronic devices and control of light propagation. In this thesis, different types of PC structure including one, two dimensional and photonic quasi crystal were applied on the GaN-based materials to develop different functional GaN-based PC lasers. First, GaN-based one dimensional PC also called high contrast grating (HCG) reflectors and surface emitting lasers (SELs) were fabricated and analyzed. The fabricated GaN membrane HCG reflectors revealed high reflectivity (over 90%) at 460 nm band with large stopband width of 60 nm in the TE polarization. On the other hand, GaN-based SELs using HCG were demonstrated at room temperature. The threshold energy density supported by the Fano resonance was measured to be 0.56 mJ/cm2 and the lasing wavelength was 393.6 nm with degree of polarization of 73%. Second, GaN-based two dimensional PC surface emitting lasers (PCSELs) and nonpolar high Q nanocavities were demonstrated and characterized. For GaN-based PCSELs, the multiple scattering method was carried out to calculate the mode pattern in real, reciprocal space and threshold gains for Γ1, K2 and M3 band-edge modes. The PCSELs with different lattice geometry were also studied and compared with simulation results. GaN-based honeycomb PCSELs showed a lowest threshold condition of 1.6 mJ/cm2 among all PCSEL devices. All the simulation results showed a similar tendency to the experimental ones. One the other hand, the nonpolar GaN high quality factor (Q) PC nanocavities were demonstrated. One dominated peak of PC H2 defect nanocavities was observed at 388 nm and Q factor was measured to be approximately 4.3×103 with degree of polarization of 64% along the m-axis at 77K. Finally, GaN photonic quasi crystal nanopillars were fabricated. Lasing action was observed at threshold condition of 40 mJ/cm2 and lasing wavelength of 369 nm under smaller pumping spot of about 15 μm2 at room temperature. One localized lasing mode was observed in the near field image and confirmed by mode pattern in real and reciprocal space. The localized lasing spot was estimated to be 3.6 μm which was matched to the divergence angle. These abovementioned GaN-based PC lasers presented various characteristics and functions. We believe these GaN-based PC lasers can be applied to visible light and UV lasers in high power laser, photonic integrated circuit, laser display application and projection system.