In this thesis, we firstly fabricated HfO2/GaSb p-MOSCAPs by utilizing hydrogen plasma treatment prior to HfO2 deposition. We found that not only modulation of capacitance was increased but also leakage current was suppressed after performing hydrogen plasma treatment. We used Berglund method and conductance method to extract interface states density (Dit). Dit value of 5x1012 eV-1cm-2 was achieved after performing forming gas annealing. By X-ray photoelectron spectroscopy (XPS), we realized that the native oxides of GaSb could be eliminated by hydrogen plasma treatment. Moreover, as confirmed in atomic force microscopy (AFM), we found that the surface of GaSb was smoother once hydrogen plasma treatment was applied. Secondly, we successfully formed Ni-GaSb alloy at 250℃ for 1 minute by rapid thermal annealing (RTA). Strong Schottky behavior was observed in the I-V characteristic of Ni-GaSb/n-GaSb junction, which had large Ion/Ioff (~103 ) and low ideal factor (~1.2). Nevertheless, large junction reverse current was observed at high annealing temperature or long annealing time. As annealing temperature reached higher than 350℃, various crystal orientation of NiSb was formed and also agglomeration was observed, leading to large junction leakage current. NiSb was formed at 250℃ for annealing time longer than 5 minutes as well. Besides, we found that Ni, Ga and Sb would diffuse during annealing process. Finally, we successfully fabricated GaSb channel PMOSFETs with HfO2 as gate dielectric as well as Ni-GaSb as S/D. Although on/off ratio (~4 orders) of source current was achieved, extremely low on/off ratio of drain current was also observed owing to large junction leakage current. Besides, ultra-low hole mobility (~22cm2V-1s-1) was extracted by means of split CV method. Also, we discussed the drawbacks, problems and trade-off of the process we adopted for fabricating PMOSFETs.