Andrew C.A. Chen

Glassy nematic conjugated oligomers: materials for organic light-emitting diodes

Conjugated organic molecules and polymers are of great interest for applications as the active element in new types of electroluminescent, photovoltaic, and electronic devices. Control of the molecular order of these materials can have a significant impact on their optical and electronic properties. In particular, alignment of conjugated organics that exhibit an intrinsic anisotropy in a dipole moment permits generation of thin films that emit linearly polarized light in an orientation specific to the alignment direction of the molecule. Polarized photoluminescence and electroluminescence from ordered conjugated oligomers and polymers has been demonstrated using many alignment methods, but particular success in integrating these materials into electrical devices has been achieved by utilizing conjugated materials that exhibit a glassy nematic liquid-crystalline phase. We report the status of our ongoing development of OLED devices based on glassy nematic oligofluorenes. These devices exhibit electroluminescent peak polarization ratios as high as 31:1 and color coordinates spanning the entire visible spectrum.

64.1: Invited Paper: Polarized OLEDS as Backlight for Liquid Crystal Displays

This work aims at the design, synthesis, and characterization of novel conjugated glassy-nematic liquid crystals for highly efficient and strongly polarized OLEDs. In addition to deep blue emission using oligofluorenes, emission of standard green, red, and white-light has also been accomplished through chemical modification and physical doping.

Novel Organic Light-Emitting Materials Capable of Variable Charge Injection and Transport

Novel organic materials were designed and synthesized by attaching monodisperse oligofluorenes to a hole- and an electron-conducting core through a flexible spacer. These material class holds promise for the realization of efficient and stable OLEDs. Article not available.

Temporal Stability of Blue OLEDs: Effect of Hole Mobility through the Emissive Layer

Anthracene-containing model compounds were synthesized to investigate causes of instability in blue OLEDs. Transient OLED measurements revealed that an emissive layer with higher hole mobility resulted in a longer lifetime at the expense of efficiency. Article not available.

Novel light-emitting organic materials with variable electron and hole conductivities

Novel organic materials are constructed by attaching monodisperse oligofluorenes to a hole- or an electron-conducting core through a flexible spacer. These materials exhibit desirable properties for use in polarized and unpolarized light-emitting diodes, such as the ability to form morphologically stable glassy liquid crystalline and amorphous films with elevated glass transition temperatures, capability for full-color emission, tunability of charge injection and transport, and ultimately achieving superior OLED device efficiency and lifetime.