系统间交叉
材料科学
量子效率
激子
电致发光
光电子学
荧光
半最大全宽
准分子
亮度
二极管
光化学
放大自发辐射
发光二极管
圆极化
有机发光二极管
光学
量子
工作(物理)
作者
Wei-Chen Guo,Zhen Chen,Meng Li,Chuan-Feng Chen,Wei-Chen Guo,Zhen Chen,Meng Li,Chuan-Feng Chen
标识
DOI:10.1002/adom.202502776
摘要
Abstract Recently, B,N‐embedded helicenes have emerged as promising candidates for high‐performance circularly polarized electroluminescence (CPEL). However, their intrinsically long delayed fluorescence lifetimes and slow reverse intersystem crossing (RISC) severely limit exciton utilization, resulting in serious efficiency roll‐off under high current density. To address this issue, an indolocarbazole fused B,N‐embedded [9]helicene ( IBN9H ) is designed and synthesized. It is found that IBN9H showed significantly accelerated RISC process and suppressed triplet exciton accumulation. Consequently, IBN9H exhibits intense emission at 526 nm with full width at half maximum (FWHM) of 0.11 eV, a short delayed fluorescence lifetime of 7.2 µs, and a high RISC rate of 3.96 × 10 5 s −1 , which represents the highest among reported B,N‐embedded helicenes. Notably, CP‐OLEDs based on IBN9H shows a maximum external quantum efficiency (EQE max ) of 33.5% with low efficiency roll‐off (EQE > 24.0% at 10,000 cd m − 2 ), a maximum luminance over 100,000 cd m − 2 , and intense CPEL with | g EL | of 2.7 × 10 −3 . This work presents a rational molecular design strategy to reduce the efficiency roll‐off in B,N‐embedded helicenes, and provides a promising CPEL material with excellent overall performances.
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