Boosting external quantum efficiency to 38.6% of sky-blue delayed fluorescence molecules by optimizing horizontal dipole orientation

To achieve high electroluminescence efficiency, great efforts are devoted to enhancing photoluminescence quantum yield (Phi(PL)) and exciton utilization of luminescent molecule, while another important factor, light outcoupling efficiency (eta(out)), receives less attention in molecule design. Here, we focus on horizontal dipole orientation engineering of the molecule to increase eta(out) and external quantum efficiency (eta(ext)). A series of tailor-made luminescent molecules consisting of an electron-accepting carbonyl core plus double electron-donating groups of spiro[acridine-9,9'-fluorene] and carbazole derivatives [e.g., 1,3,5-tri(carbazol-9-yl)benzene] are developed and systematically investigated. These molecules hold distinguished merits of strong sky-blue delayed fluorescence with excellent Phi(PL) values, large horizontal dipole ratios, and balanced bipolar carrier transport, which furnish record-high eta(ext) values of up to 26.1 and 38.6% in nondoped and doped sky-blue organic light-emitting diodes (OLEDs), respectively. Moreover, the state-of-the-art nondoped hybrid white OLED and all-fluorescence single-emitting layer white OLED are also realized, demonstrating great potentials in OLED industry of these molecules.

Automated summary

Efforts have been focused on enhancing electroluminescence efficiency by engineering horizontal dipole orientation of luminescent molecules, leading to record-high eta(ext) values in both doped and nondoped sky-blue OLEDs. These tailor-made molecules exhibit strong sky-blue delayed fluorescence with excellent Phi(PL) values, large horizontal dipole ratios, and balanced carrier transport, showing great potential in OLED industry.