Abstract
This paper presents an efficient and stable green inverted organic light emitting diode (IOLED) using multifunctional and strong nucleophilic quality electron transport material (1,3-bis(2-phenyl-1,10-phenanthrolin-4-yl)benzene ( m -bPPhenB)) with silver (Ag) as an n -dopant. By the energy level alignment study using in-situ ultraviolet photoelectron spectroscopy measurement, negligible electron injection barrier between indium tin oxide (ITO) and Ag-doped m -bPPhenB (Φ e ≈ 0.03 eV) is observed and the electrons can be easily tunneled from ITO into Ag-doped m -bPPhenB layer. Also, Ag dopant forms coordination bonds with phenanthroline based unit, which improves electron injection from ITO. Fabricated IOLED devices using an Ag-doped m -bPPhenB have an extremely low driving voltage of 3.6 V and external quantum efficiency of 29.0%. Such good performances of IOLED are attributed to negligible electron injection barrier at the interface between ITO and Ag-doped m -bPPhenB. The Ag-doped IOLED device also shows a good air stability owing to the stable Ag n -dopant. The doping of Ag into special electron transport layer in the IOLED structure could be applicable to various displays and lighting applications. • We fabricated efficient and stable green IOLEDs by using m -bPPhenB:Ag ETL. • A negligible electron injection barrier observed between ITO and m -bPPhenB:Ag. • IOLED showed low driving voltage, high EQE, and good stability.
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