Graphene is arranged from the carbon atoms and the adjacent carbon atom with a covalent bond, forming sp2 hybridization. It is a two-dimensional material which arranges in a hexagonal honeycomb structure. Graphene has advantages such as high carrier mobility, high transmittance, low resistivity and good thermal properties, among those advantages the high transmittance in UV region is the most significant characteristic, so we applied the graphene on UVCLED as transparent conductivity electrode. However, the key of applying the graphene on UVCLED is the contact problem between the graphene and the surface material of UVCLED. In the thesis, we proposed using atomic layer chemical vapor deposition to deposit nickel oxide as the buffer layer decreasing the Schottky barrier height, which also improved the poor contact. We also dedicated to directly growing large-scale graphene by plasma-enhanced chemical vapor deposition(PECVD). Using nickel film as a metal catalyst, we directly grew graphene on the substrate. Obviously, we could apply the graphene without transferring process. It makes large area production of graphene be feasible, at the same time it decreases the process temperature to confirm the thermal budget. Finally, we deposited nickel oxide and directly grew about four layers of graphene on the p-GaN, then measuring the contact resistance is (2.29 ± 0.73) × 10-1Ω-cm2. The transmittance of graphene with nickel oxide is 62.1%. It shows graphene is the potential material to replace indium tin oxide as a transparent conductive electrode of UVCLED.