Research topics

Excited spices in organic semiconductors generated by photon or electrical excitation can relax to the ground state in radiative or non-radiative manner. The emissive relaxation plays an important role for their applications in light emitting devices, while dark processes are kinetically completion loss channels.
The purpose of this sub-project is to quantitatively investigate the excition dynamic for both the emissive and dark processes. We are using ultrafast absorption and time-resolved photoluminescence spectroscopy techniques to experimentally verify these processes. Specifically, we are interested in organic semicondcutors with photophysical properties such as thermally activated delayed fluorescence, room temperature phosphorescence and/or stimulated emission. We anticipate the understanding of ultrafast exciton dynamics can facilitate the development of optoelectronic devices.

Light generated from emissive excitons inside light emitting diodes can only partially escape the device cavity. Significant light trapping is observed because of total internal reflection and light coupling into the metallic electrode surface.  In this sub-project, we try to numerically simulate the optical outcoupling efficiency for LEDs, with the consideration of electrical and optical properties simultaneously.  The aim is to develop efficient and stable light emitting devices.