Excellent properties of the field emission devices made them be greatly potential in the flexible lighting recently. The carbon nanotube thin films (CNTFs) had competitive advantages of remarkable mechanical strength, outstanding chemical stability, and high conductivity on the applications of the cathodes in the large-area and the low-cost flexible field emission lighting devices (FELDs). However, applying the CNTFs as the cathodes of the FELDs encountered the challenges of severe screening effect, the choice of the flexible substrate, the adhesion issue, and the uniformity issue. With the theoretical simulation and the device realization in this thesis, the techniques of applying the CNTFs on the micro-structured flexible substrates for the FELDs were established. Using the potassium hydroxide (KOH) solution to etch the (100) silicon wafers as the templates which were used to transfer the pyramid structures to the polydimethylsilicone (PDMS) for the flexible FELDs to reduce the screening effect, applying the O2 plasma treatment on the surface of PDMS for improving the adhesion, and using the scanning-ultrasonic-spray techniques to deposit the uniform CNTFs on the flexible microstructured PDMS, a high-performance flexible lighting devices could be thereby easily fabricated. Technology Computer Aided Design (TCAD) simulation software was applied to investigate the effects of the microstructures on the field emission characteristics. By designing of the height(H) and the interspacing(R) of the pyramid microstructures, we generalized that there were the “height effect” and the “R/H ratio effect” would affect the electrical fields on the pyramid tips. We also successfully found the optimum pyramid microstructure with the pyramid height of 30 μm and R/H of 2. According to the simulation results, we fabricated the samples with different R/H ratios by the mask design and KOH solution anisotropic etching on the (100) silicon wafers, and then transferred the pyramid structures on the etched silicon to the flexible PDMS. The CNT solution was then uniformly scanning-ultrasonic-sprayed on the pyramid-structured PDMS substrates and the measurements of field emission characteristics were completed. The field emission characteristics of the CNTFs on the pyramid-structured PDMS with the pyramid height of 30 μm and R/H of 2 are obviously superior to the CNTFs on the planar PDMS. The experiment results are consistent with the simulation results. It is a significant proof that the microstructured substrates can greatly reduce the screening effect and enhance the characteristics of the FELDs. In addition, for improving the adhesion between the CNTF and the PDMS, the O2 plasma treatment on the surface of PDMS was proposed. The bias powers were modulated to control the ion bombardment on the PDMS. For the bias power of 70 W, the contact angle of DI water on the PDMS changed from 105.59゜(hydrophobic ) to 14.55゜(hydrophilic). Therefore, the adhesion-improved CNTFs on the pyramid-structured PDMS with the pyramid height of 30 μm , R/H of 2 and the bias power of 70 W had the optimum field emission characteristics with the turn on field of 1.39 V/μm. In the reliability test at 4 V/μm for 6000 sec, there is a much stable emission current density of 200 μA/cm2 as compared to the emission current density of 2~3 μA/cm2 without O2 plasma treatment. These results indicated that the O2 plasma treatment on the PDMS will significant improve the adhesion between the CNTFs and the PDMS.