Organic light-emitting devices (OLEDs) have attracted growing interest for display and lighting applications in the past decade. Traditionally, the efficiency of light emission from traditional fluorescent OLEDs is limited since only the singlet states of the organic molecules contribute to the light emission. Recent demonstration of phosphorescent OLEDs renders possible achieving 100% internal quantum efficiency in OLEDs. Such an ideal had been readily demonstrated for red and green phosphorescent devices. On the other hand, there still requires much effort for blue devices. Therefore, a major part of the present dissertation is dedicated to the development of novel materials and device structures for improving blue phosphorescent OLEDs. Another focus of this dissertation is the research of single-layer devices which strongly benefit the simplification of the manufacturing processes of OLEDs. In the first part of this dissertation, novel phosporescent dopants are developed and investigated. A multifunctional host is also proposed to fabricate highly efficient single-layer red phosphorescent AOLEDs. An important issue of blue phosphorescent OLEDs is the development of high-triplet-energy host materials. Therefore, hole-transporting hosts satisfying such demanding are demonstrated by different molecular design strategies. Subsequently, the electron-transporting counterparts with high triplet energy are studied. In addition, potential electron-blocking/exciton-blocking materials are also proposed. In the second part of this dissertation, multifunctional, ambipolar, and high-triplet-energy hosts are studied for usage in fabrication of highly efficient single-layer red, green, and blue phosphorescent OLEDs. The development of large-gap phosphorescent complexes inspires the studying of novel phosphorescent host/phosphorescent dopant devices utilizing the effective Förster energy-transfer mechanism. In the final part, hybrid fluorescent/phosphorescent white OLEDs are studied considering possible applications in solid-state lighting.