Our lab will shape the future of display technologies, driving innovation to meet next-generation demands. 

Through a combination of breakthroughs in advanced simulation, AI integration, and revolutionary device engineering, we aim to push the boundaries of what displays can achieve. 

Join us on this exciting journey to redefine the way we experience the world through next-generation displays! 

Optimization system modeling

For next-generation optoelectronics, precise optimizations tailored to specific applications will be essential. Revealing the charge transport mechanism and exciton dynamics is essential for improving the device performance. Furthermore, intriguing phenomena such as the microcavity effect, Purcell effect, light-matter interactions, and optical coherence play a crucial role in cavity structures.

By leveraging advanced optoelectrical simulation, we provide valuable insights toward the realization of next-generation displays, including AR/VR and holographic technologies. 

Additionally, the optimization process can be made more efficient and systematic through the integration of AI technology, simplifying complex design challenges.

Device engineering

Thanks to the exceptional optical properties of quantum-dots (QDs), including their narrow emission bandwidth and high quantum yield, QD-based LEDs and lasers are considered a promising optoelectronic device for next-generation display applications. Significant efforts have been made to commercialize QD optoelectronics, with notable progress achieved through advanced device & material design, as well as outcoupling technology.

Building on insights from optimization model, we explore strategies rooted in device physics and photonics to realize optimized light-emitting devices.