Discrimination of Degradation Mechanisms for Organic Light-Emitting Diodes by In Situ, Layer-Specific Spectroscopic Analysis

The irreversible loss of emission intensity of the organic light-emitting diode (OLED) device under extended operation is the most important issue in OLED technology and industry. Since the typical OLED device has a multilayer structure, it is imperative to know what happens in each layer photophysically and photochemically under operating conditions in order to pin down the root cause and improve OLED performance. We here present a new, nondestructive method that allows in situ, layer-specific analysis of OLED devices. To demonstrate our technique, we fabricated a three-layer OLED device with materials in each layer having distinct emission spectrum and lifetime from one another so that photophysical and photochemical changes can be tracked virtually independently in each layer. Specifically, by measuring the luminescence intensity and lifetime, photochemical bleaching and photophysical quenching of the materials were decoupled. In accord with previous studies, charge transport was found to be of limited importance, while quenching played a more significant and persistent role. Of particular interest is the predominant role of bleaching that has been largely overlooked in spectroscopic studies.