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Lens-free OLED with efficiency comparable to inorganic LED:


The use of organic light-emitting diodes (O LEDs) has extended to various applications, but their efficiency is still lagging behind inorganic LEDs. A KAIST team says it has provided a systematic way to yield OLEDs with an external quantum efficiency (EQE) greater than 50% with an external scattering medium. 
Having properties suitable for thin and flexible devices, OLEDs are popular light sources for displays, such as mobile devices and high quality TVs. In recent years, numerous efforts have been made to apply OLEDs in lighting as well as light sources for vehicles.
For such applications, high efficiency is of the upmost importance for the successful deployment of light sources. Thanks to continuous research and the development of OLEDs, their efficiency is steadily on the rise, and a level equivalent to inorganic LEDs has been demonstrated in some reports. However, these highly efficient OLEDs were often achieved with a macroscopic lens or complex internal nanostructures, which undermines the key advantages of OLEDs as affordable planar light sources, and tends to hinder their stable operation. As a result, their commercialisation has been limited.
Among various methods proven effective for OLED light extraction, a team led by Professor Seunghyup Yoo at the School of Electrical Engineering at KAIST, focused on the external scattering-based approach. This technique can maintain planar geometry and compatibility with flexibility, can be fabricated on a large scale at a low cost, and causes no interference with electrical properties of OLEDs.
Conventionally, research on enhancing OLED light extraction using light scattering has been conducted empirically in many cases. This time, the team developed comprehensive and analytical methodology to theoretically predict structures that maximise efficiency.
Considering OLEDs with the external scattering layers as a whole rather than two separate entities, the researchers combined the mathematical description of the scattering phenomena with the optical model for light emission within an OLED to rapidly predict the characteristics of many devices with various structures. Based on this approach, the team theoretically predicted the optimal combination of scattering layers and OLED architectures that can lead to the maximum efficiency.
Following this theoretical prediction, the team experimentally produced the optimal light scattering film and incorporated it to OLEDs with orange emitters having a high degree of horizontal dipole orientation. As a result, the team successfully realised OLEDs exhibiting EQE of 56% and power efficiency of 221 lm/W. According to KAIST, this is one of the highest efficiencies ever realised for an OLED unit device without the help of a macroscopic lens or internal light extraction structures.
Professor Yoo said, “There are various technologies developed for improving OLED light extraction efficiency. Nevertheless, most of them have not reached a level of practical use. This research mainly provides a systematic way to attain an EQE of 50% or higher in OLEDs while keeping in mind the constraints for commercialisation. The approach shown here can readily be applied to lighting devices or sensors of wearable devices.”

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