In this thesis, the amorphous SiGe thin film is deposited by ICPCVD at low temperature of 450oC, the SiGe thin film is then crystallized by visible laser crystallization (λ=532 nm). The grain size of as-crystallized poly-SiGe thin films range from 500 nm to 600 nm. It is found that germanium segregation is observed after laser crystallization. It causes germanium-rich region on surface of the thin film. Thus, Chemical Mechanical Polishing (CMP) is used to polish high germanium concentration region and smoothen the surface to obtain thin and flat ploy SiGe film with uniform germanium concentration distribution. Moreover, far infrared ray laser annealing (FIR-LA) can decrease sheet resistance. Laser energy is absorbed in implantation induced defect region and transfer to phonon vibration, which is equal to thermal activation effectively. . In this study, the sheet resistance of polycrystalline SiGe film can be decreased to 290 Ohm/sq. (P-type) and 350 Ohm/sq. (N-type) by far infrared ray laser annealing with less dopants diffusion due to the short time dwell time. Therefore, FIR-LA is also suitable for realizing nano-scaled devices. The combination of visible laser crystallized SiGe film and far-infrared ray laser activation demonstrated the high performance of poly SiGe metal-oxide-silicon field effect transistor (MOSFET), which exhibited high on current of 51.3 uA/um, low subthreshold swing (S.S.) of 181 mV/dec. and threshold voltage (Vth) of -1.05 V in P-type FET. The N-type device exhibited Ion of 20.1 uA/um, S.S. of 240 mV/dec, and Vth of 0.95 V. The process and related performance is of great potential for nano-scaled TFTs and monolithic 3DICs applications.