Moore’s Law, which predicts that the numbers of transistors on the same chip will increase by 2-fold every 1.5 years, has remained valid since it was proposed in 1965. However, as the scale of the Silicon based devices reaches a few nanometers, many theoretical limits have also been reached. 2D materials, such as graphene and MoS2, have the potential of replacing Silicon-based devices due to their atomic-scale thickness and other interesting properties. However, the contact resistance between metal contacts and 2D materials such as MoS2 is way higher than that of the Silicon bulk counterpart. This problem of high contact resistance significantly suppresses the charge injection between the metal electrode and the 2D-semiconductor channel and therefore limits future developments of 2D-devices. Take an example from MoS2, the surface dipole formation, defects, and metal-induced gap states (MIGS) cause fermi level pinning, which means that we can no longer adjust the Schottky barrier height by changing the work function of our metal contacts. We developed a new deposition technique which allows us to produce a matrix of electrodes made by different compositions of two metals on a single sample. We can then characterize these alloy contacts either to compare the contact resistance of the two metals, or to find out if there is any specific composition of alloy that can improve the charge injection and lower the contact resistance. In the following experiments, we successfully compared the contact resistance of graphene between Titanium and Silver, and identified a specific composition of Indium and Bismuth which improves the charge injection between MoS2 and our contacts.