We directly synthesized multi-layer graphene with an area of several hundred square microns on the lithium niobate (LN, LiNbO₃) substrate by Carbon (C) implantation into the copper (Cu)-covered LiNbO₃. The energy of C ion implantation was optimized per SRIM simulation to ensure that the distribution of C covers the Cu/LiNbO₃ interface. The optimized energy was established at 55 keV, such that the formation of C peaks in the respective materials on each side of the Cu/LiNbO₃ interface. The diffusion of the accumulated C to the Cu/LiNbO₃ interface can form a more uniform C distribution at the interface, which is beneficial to the synthesis of graphene. Following the annealing process and removal of the Cu coating, a multi-layer graphene with an area of several hundred square microns on the surface of LiNbO₃ was identified and characterized using Scanning Electron Microscopy (SEM), Energy-Dispersive x-ray Spectroscopy (EDS), Raman spectroscopy, and Atomic Force Microscopy (AFM). This remarkable advancement encourages the industrialization of direct graphene synthesis on LiNbO₃ substrates via ion implantation.