Low-temperature polycrystalline silicon (LTPS) thin-film transistors (TFTs) have been widely used in active matrix flat panel displays (AMFPDs), since they demonstrated much higher field-effect mobility and lower power consumption than the conventional amorphous silicon (α-Si) TFTs. There were several technologies for LTPS thin films, including solid phase crystallization (SPC), metal-induced crystallization (MIC), metal-induced lateral crystallization (MILC), excimer laser crystallization (ELC), and continuous wave laser crystallization (CLC). These approaches all could effectively transform the α-Si thin films as the polycrystalline silicon (poly-Si) thin films. Among these technologies, the grain size of poly-Si thin films fabricated by the CLC was the biggest. In addition, the CLC poly-Si thin films possessed the excellent crystallinity and flat surface morphology. Thus, the CLC poly-Si TFTs usually could demonstrate high performance and superior reliability. According to the previous researches, it was also found that the CLC poly-Si thin films possessed biaxial tensile strain which could effectively improve the carrier mobility. To realize such an effect and observe the mobility enhancement for the CLC poly-Si TFTs, the spacer technology to obtain nanowire structures was applied to avoid the grain boundaries. At first, the material analysis for the CLC poly-Si thin films was investigated. The CLC poly-Si thin films possessed the grain size of 2 μm* 20 μm, flat surface morphology, excellent crystallinity, and the induced thermal stress of about 800 MPa. Meanwhile, the phenomenon of strain relaxation by the pattern effect was also discussed here. The results indicated that the biaxial tensile strain in the CLC poly-Si thin films would become uniaxial tensile strain when the CLC poly-Si thin films were patterned as the CLC poly-Si nanowires. In the second part, the electrical characteristics of the CLC poly-Si TFTs were studied. First, the comparisons of electrical characteristics between the planar CLC poly-Si TFTs and the tri-gate CLC poly-Si NW TFTs would be conducted. The results presented that the planar CLC poly-Si TFTs with L/W = 2μm/ 1μm attained the μFE of 625 cm2V-1s-1, subthreshold swing (S.S.) of 588 mV/decade, threshold voltage (Vth) of -3 V. In contrast, the tri-gate CLC poly-Si NW TFTs with L/Weff = 2μm/ 1μm achieved the μFE of 825 cm2V-1s-1, S.S. of 196 mV/decade, and Vth of -1 V. It was observed that the tri-gate CLC poly-Si NW TFTs demonstrated much better performance than the planar ones owing to the strain enhancement, better crystallinity, and better gate control ability. The tri-gate CLC poly-Si NW TFTs successfully avoided the grain boundaries in the channel regions of the devices. On the other hand, the p-type tri-gate CLC poly-Si NW TFTs with L/Weff = 3 μm/ 4 μm also achieved μFE of 217 cm2V-1s-1. The strain enhancement for the p-type devices was not so obvious. According to previous researches, it was found that the uniaxial tensile strain was not helpful for improving the hole mobility. Finally, the dependence of μFE on the temperature for the tri-gate CLC poly-Si NW TFTs was also examined. The results indicated that the tri-gate CLC poly-Si NW TFTs exhibited the single-grain-like characteristics. The high-performance tri-gate TFTs with the strained poly-Si NWs via the CLC have been successfully fabricated to be promising for the application in the future system on a panel (SOP) and three-dimensional integrated circuits (3D-ICs).