Abstract
Our effort in improving the performance of light-emitting materials and devices have been focused on three main areas: 1) modify the interface between light-emitting polymers and electrodes for better charge injection; 2) develop in-situ crosslinkable hole-transporting polymers to facilitate multilayer solution processing and cascade hole-injection and transport; and 3) enhance the efficiency of polymer LEDs through the development of new conjugated materials with balanced charge-transporting properties. In this talk, we will review our recent progress using dipolar self-assemble monolayer (SAM) to form dense assembly on indium tin oxide (ITO) to tune the energy barrier between ITO and hole-transporting polymers. We have systematically determined these barriers using the internal photoemission technique. Several in-situ polymerizable hole-transporting materials with desirable energy level were also developed to facilitate cascade hole-injection for quantum dot (QD)- and blue phosphorescent dopant-based LEDs. In addition to these efforts, a series of neutral surfactants were also employed to modify the energy barrier between light-emitting layer and several high work function cathodes, such as Al, Ag and Au. As a result of this integrated materials development approach, stable, very efficient and bright light-emitting devices have been demonstrated for applications in displays and solid-state lighting.
© 2007 APS DLS
PDF ArticleMore Like This
Yuguang Ma
OTuD4 Organic Materials and Devices for Displays and Energy Conversion (OMD) 2007
Russell J. Holmes
LM3A.1 Solid-State and Organic Lighting (SOLED) 2012
Sang-Hyun Eom, Edward Wrzesniewski, Jaewon Lee, Neetu Chopra, Debasis Bera, Paul H. Holloway, Franky So, and Jiangeng Xue
SDWC6 Solid-State and Organic Lighting (SOLED) 2011