OLED technology is widely used in mobile devices, AR/VR systems, and automotive displays, with its flexibility enabling foldable devices and enhanced user interactions. However, advancing OLEDs requires overcoming challenges such as improving efficiency, extending lifetime, ensuring color stability, and optimizing scalable manufacturing. Since device performance depends on both material properties and fabrication methods, a deeper understanding of OLED materials and device architectures is essential for innovation.

Traditional trial-and-error approaches to materials discovery are costly and time-consuming. To address this, we present the synergistic application of Ansys and Schrödinger predictive technologies to accelerate OLED development through a multi-scale, multi-physics simulation approach. This framework integrates:

• Molecular modeling to predict materials properties at atomistic scale

• Nanoscale simulations to examine photonic responses and light-matter interactions

• Macroscale modeling to assess human perception of displays in real-world conditions

By combining Schrödinger’s expertise in molecular simulations with Ansys’s advanced device modeling, this approach enables faster, cost-effective OLED innovation. Join us to explore how integrated digital workflows drive the design of next-generation, high-performance OLEDs.