Abstract
Improving the efficiency of organic light-emitting diodes (OLEDs) by enhancing light outcoupling is common practise and remains relevant as not all optical losses can be avoided. Especially, externally attached scattering layers combine several advantages. They can significantly increase the performance and neither compromise the electric operation nor add high costs during fabrication. Efficiency evaluations of external scattering layers are often done with lab scale OLEDs. In this work we therefore study different characterization techniques of red, green and blue lab scale OLEDs with attached light scattering foils comprising TiO2 particles. Although we observe an increased external quantum efficiency (EQE) with scattering foils, our analysis indicates that areas outside the active area have a significant contribution. This demonstrates that caution is required when efficiency conclusions are transferred to large area applications, for which effects that scale with the edges become less significant. We propose to investigate brightness profiles additionally to a standard EQE characterizations as latter only work if the lateral scattering length is much smaller than the width of the active area of the OLED. Our results are important to achieve more reliable predictions as well as a higher degree of comparability between different research groups in future.
Highlights
Improving the efficiency of organic light-emitting diodes (OLEDs) by enhancing light outcoupling is common practise and remains relevant as not all optical losses can be avoided
We focus on carefully quantifying the light outcoupling of OLEDs comprising external scattering layers for the case of finite size devices where edge effects cannot be ignored
Our results show the complexity of OLED characterisation with external scattering foils
Summary
Improving the efficiency of organic light-emitting diodes (OLEDs) by enhancing light outcoupling is common practise and remains relevant as not all optical losses can be avoided. Externally attached scattering layers combine several advantages They can significantly increase the performance and neither compromise the electric operation nor add high costs during fabrication. To open further markets a constant development is needed regarding costs, lifetime and efficiency The latter is mainly limited by the inherent high refractive index of the materials, which leads to optical confinement of photons in the planarized multi-layer structure[1,2]. External light outcoupling structures are attached to the outer surface of the substrate. This leads to reduced reflection at the glass-air interface. While optical simulations are being developed to predict optimal scattering structures[32,33], the experimentalists are lacking of standardized
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