1. The Applications of Spirobifluorene-configured Bipolar Materials in Photovoltaics and Electrophosphorescence Devices Spirobifluorene-configured bipolar materials, consisting of donor (D) and acceptor (A) moiety, are potentially capable of carrying both holes and electrons. These bipolar materials, possessing reversible oxidation and reduction behavior, can be considered as a promising matrix for hole and electron transporting. Here we demonstrate the applications of spirobifluorene-bridged bipolar derivatives in photovoltaics and electrophosphorescence devices. A D-A system with efficient photon-to-electron conversion requires effective charge separation from optically generated excitons. Such D/A interfaces may be implemented by putting D/A chromophores in layered structures, in blends (mixtures), or even in chemically linked structures. The chemical blends can achieve a highly efficient charge separation, but the chemical syntheses are sophisticated. Hence physical blends could be another much easier way to achieve such purpose. Therefore we designed and synthesized novel donor and acceptor molecules incorporated thiophene and benzothiadiazole moieties with 9,9’-spirobifluorene, respectively, and investigated them in photovoltaic applications. On the other hand, a highly efficient electrophosporescent device with a simple device structure giving saturated red emission (CIE at x=0.66, y=0.34) has been achieved by doping an iridium complex (Mpq2Iracac) into a novel, ambipolar, spiro-configured D-A host material. After introducing cyano groups and diarylamine moieties into different biphenyl branches of 9,9’-spirobifluorene, respectively, it possesses balanced electron- and hole-transporting ability, suitable HOMO/LUMOlevels for carrier injection from an electrode, and an appropriate triplet energy gap for a red guest. The device configured as: ITO/HIL (Hole Injection Layer)/D-A host:Mpq2Iracac/LiF/Al, exhibited a highly efficient electrophosporescent device with a simple device structure. 2. The Applications of Benzothiadiazole Derivatives in Electrogenerated ChemiLuminescence (ECL) and Surface Patterning Directed by Scanning Electrochemical Microscopy (SECM) Promoted Click Chemistry Benzothiadiazole derivatives, possessing highly efficient green light emission, are very useful in light-emitting devices. Here we demonstrated the applications of benzothiadiazole derivatives in electro-generated chemiluminescence (ECL) and surface patterning directed by scanning electrochemical microscopy (SECM) promoted click chemistry. A series of highly fluorescent benzothiadiazole derivatives (BH0−BH3) and fluorene derivatives (AB2, C01, FAF, FPF, and FDF) were synthesized and characterized. By cyclic voltammetric study, we unveiled the relationships between molecular structure and electrochemical properties. These highly fluorescent benzothiadiazole derivatives with reversible oxidation and reduction waves are applied for green ECL. The ECL could be seen by the naked eye even in a well lit room. Such strong ECL emitters are not common in the field of electrogenerated chemiluminescence, especially for green ECL emitters. SECM-based surface patterning can be achieved to form useful micro/nano structures for various kinds of applications. Alkyne functionalized benzothiadiazole derivatives can be transformed into a triazole ring with a azide-terminated reagent anchored on a substrate. Here we reported a novel SECM-based surface patterning of fluorescence molecules on a solid substrate, by proceeding with click chemistry reaction to form a covalent bond and. The pattern image can be observed from a fluorescence microscopy.