The selectivity of ethylene formation from the hydrogenation of acetylene could be tuned to 100% in our catalytic surface design, Fe(1,2)@W(111), in which the first two layers of W(111) surface is replaced by the Fe atoms. There are three possible reaction pathways in the hydrogenation of acetylene carried out on the catalytic metal surfaces: (1) solely formation of ethylene then desorbed from the surface; (2) complete hydrogenation to ethyl radical then ethane; (3) decompose to two methylene fragments. We introduced several monometallic and bimetallic surfaces (W(111), Fe(1,2)@W(111), Fe(111), W(1,2)@Fe(111), Fe(1)@W(111), and W(1)@Fe(111); where Fe(1)@W(111) represents the top layer of tungsten (111) surface replaced by the iron atoms, while W(1)@Fe(111) denotes the tungsten atoms replacing the first layer iron (111) surface ) to systematically tune the selectivity of ethylene formation via acetylene hydrogenation by employing DFT (density functional theory) calculations. On Fe(1,2)@W(111) surface, the barrier of ethylene formation is only 0.84 eV, the smallest among those bimetallic surfaces, and the barrier of further hydrogenation to C2H5 is 2.43 eV, while the alternative pathway of C-C bond scission is 2.27eV; these two latter barriers are much higher than C2H4 desorption energy (0.42eV). Therefore, the ethylene molecule could be the sole and final product to be desorbed from the catalytic tuned Fe(1,2)@W(111) surface.