Organic optoelectronic devices have attracted intense attention from researchers and companies all over the world for their low cost, ease of production, and mechanical flexibility compared to traditional inorganic optoelectronic devices. Among various aromatic molecules, fluorene is rigid with high photoluminescence quantum yield (PLQY). With proper modification, physical and chemical properties of fluorene derivatives can be easily tuned. As a consequence, fluorene-based molecules are widely used in organic optoelectronic devices. In this thesis, a series of fluorene-based organic optoelectronic materials utilized in organic light-emitting diodes (OLEDs) and organic laser were designed, synthesized, and characterized. In the 1st chapter, organic optoelectronic devices and characteristics of fluorene were briefly introduced. The 2nd and 3rd chapters elaborate the concept of improving the efficiency of blue emission device by applying exciplex system in OLED devices. In the 2nd chapter, the idea for energy level adjustment on hole-transporting materials (HTMs) by introducing electron-withdrawing cyano group was demonstrated. It is expected that the resulting exciplexes with wider optical energy gaps may serve as deep blue hosts for blue emitters. On the other hand, the 3rd chapter focuses on novel electron-transporting materials (ETMs) for exciplex-based OLED. In order to adjust the energy levels of the lowest unoccupied molecular orbital (LUMO), electron-withdrawing cyano group was introduced onto different positions of the fluorene core. Thus, a series of ETMs for deep blue exciplex were synthesized and examined. The 4th chapter manifests the concept of intramolecular triplet-triplet annihilation (TTA) emitter, and it shows great promise for blue emission devices. In this regard, fluorene serves as bridge to link two diphenylanthracenes to realize intramolecular TTA. Last, novel design of organic laser gain materials is demonstrated in the 5th chapter. Cyano group was introduced onto the backbone of oligofluorenes to enhance dipole-dipole interaction between molecules, and thus improving the performances of organic laser devices.