Tirphenylamine is good a hole transport material with electrochemistry activity. We hope to use this moiety to synthesis triphenylamine derivatives to improve the performance of OLED, including red light emitting materials, hole transport materials. In chapter 2, the physical of red light emitting PCF dye 1 was discussed with electrochemistry, Förster energy transfer, and OLED devices. The dye-doped organic light-emitting diode shows red electroluminescence with the efficiency of 2.9 cd/A at 100 cd/m2 and maximum brightness of 62000 cd/m2. This chapter had published in Organic Lett. 2006, 8, 2623-2626 In chapter 3, we had synthesized a photo-labile organic semi-conducting polymer 1 and polymer 2 with triphenylamine moiety with photo resistance type property. The triphenylamine group served as two functions: (1) cross-linking the polymer through electro-polymerization (2) hole transport material. After UV illumination, the polymer can be selectivity dissolution; we also demonstrated an image with PLED device. This chapter had published in Chemistry of Materials. 2008, 20, 5816-5821. Finally, We use nitroxide SAM to serve as surface initiator, then growth triphenylamine polymer brush on ITO . After electro-polymerization, triarylamine polymer brushes can be dimerized and cross-link for hole transport enhancement. Surface analysis of cyclic voltammetry, UV-Vis absorption, water contact angle, and SEM had been studied in this chapter. The PLED device was optimized to 16200cd/m2 and 20.9cd/A. Through photo oxidation, polymer brushes can be selectively degradation to prepare a patterned PLED emitting device.