Toward a BT.2020 green emitter through a combined multiple resonance effect and multi-lock strategy

The authors combine multiple resonance effect and multi-lock strategy to dope green-emitting thermally activated delayed fluorescent molecules into green-emitting phosphorescence OLEDs by endowing the device with a Broadcast Service Television 2020 color-gamut, 50% improved EQE, and a high luminescence of half a million nits. Color-saturated green-emitting molecules with high Commission Internationale de L'Eclairage (CIE) y values have great potential applications for displays and imaging. Here, we linked the outer phenyl groups in multiple-resonance (MR)-type blue-emitting B (boron)-N (nitrogen) molecules through bonding and spiro-carbon bridges, resulting in rigid green emitters with thermally activated delayed fluorescence. The MR effect and multiple interlocking strategy greatly suppressed the high-frequency vibrations in the molecules, which emit green light with a full-width at half-maximum of 14 nm and a CIE y value of 0.77 in cyclohexane. These were the purest green molecules with quantum efficiency and color purity that were comparable with current best quantum dots. Doping these emitters into a traditional green-emitting phosphorescence organic light-emitting diode (OLED) endowed the device with a Broadcast Service Television 2020 color-gamut, 50% improved external quantum efficiency, and an extremely high luminescence of 5.1 x 10(5) cd/m(2), making it the greenest and brightest OLED ever reported.

Automated summary

The authors successfully doped green-emitting molecules into organic light-emitting diodes using multiple resonance effect and multi-lock strategy, achieving a device with Broadcast Service Television 2020 color-gamut, 50% improved EQE, and high luminescence. The green emitters with high color saturation and potential applications for displays and imaging were linked through bonding and spiro-carbon bridges, resulting in the purest green molecules with comparable quantum efficiency.