Computational fluid dynamics (CFD) is widely used in the semiconductor for analyzing and designing chemical vapor deposition (CVD) reactors. The CVD process is studied by various CFD simulations between 2d and 3d conditions to grow gallium-nitride (GaN) film, a sequence of reactions between gas-phase and surface-reaction which take a great influence to depositing film uniformity. The showerhead type MOCVD model is based on Ministry of Economic Affairs, R.O.C. and I.T.R.I. developing LED GaN on silicon program. This research uses CFD commercial software: ANSYS FLUENT to calculate flow, heat transfer and species transport in a vertical CVD chamber. Discretization is made by using finite volume method and the system of discretized algebra equations are solved by SIMPLE algorithm. In order to know GaN growth conditions and deposition rate, we have observed that different pressure and rotation speed caused flow and heat transfer changing in the reactor by using numerical simulation. The 2D model was design of axisymmetric, uniform gas inlet into the chamber with different conditions in this study. The results performed that the heated susceptor may cause the buoyancy effect and recirculation above the wafers. And the 3D reactor model includes of chemical gas-phase and surface-reaction mechanism. Simulation results showed the effect of important parameters, such as operating pressure, susceptor temperature, rotating speed, inlet to susceptor distance, on GaN film growth. Compare with 2d and 3d model, we found out that low pressure and high rotation speed providing better flow distribution and uniform deposition rates. These characters help stabilizing the flow and heat transfer in the chamber meanwhile they also cause the stable species transport in the reactor.