Effective exciplex system with high emission efficiency via intramolecular hydrogen bonding for efficient solution processable OLEDs

Exciplex system is a charming candidate for thermally activated delayed fluorescence (TADF) due to its intrinsic small energy difference between the lowest singlet state and triplet excited state (ΔE_ST). However, high emission efficiency and fast radiative decay rate are still a formidable task for the exciplex emission. Herein two novel tri(triazolo) triazine-based TADF emitters, named TTT-HPh-Ac and TTT-MePh-Ac, are synthesized and characterized. Using such TADF emitters as the donor molecule and (1,3,5-triazine-2,4,6-triyl)tris(benzene-3,1-dial)tris(diphenylphosphine oxide) (PO-T2T) as the acceptor molecule, the exciplex system of TTT-HPh-Ac:PO-T2T and TTT-MePh-Ac:PO-T2T are prepared, which show a tiny ΔE_ST of 40 ± 20 meV and fast reverse intersystem crossing rate. As a result, very high emission efficiency (97%) and a small non-radiative decay rate are detected for the exciplex TADF system. The solution processable organic light-emitting diode using the exciplex system as the emitter achieves a maximum external quantum efficiency (EQE_max) of 17.0%. When using the exciplex as the host matrix, the TTT-MePh-Ac:PO-T2T based solution processable device shows a better performance with an EQE_max of 20% with a very small efficiency roll-off of 6% at 1000 cd m⁻². This work proves that the molecule with both intramolecular hydrogen bonding and proper twisted molecular geometry in exciplex is more favorable to enhance its emission efficiency and suppress the non-radiative transition, which provides a new way to develop efficient and stable exciplex emitters.