电致发光
有机发光二极管
材料科学
激子
光电子学
分子内力
分子间力
电荷(物理)
二极管
纳米技术
能量转移
工程物理
有机半导体
电致发光显示器
有机电子学
化学物理
透视图(图形)
电压
作者
Qiang He,Yulong Shi,Tingting Feng,Sichao Ji,Qiyin Chen,Zhexin Song,Xiangyu Shen,Xihu Wu,Shun Li,Federico Rosei,Jianming Zhang,Chengshao Yang,Ruidong Zhu,Qingshan Shan,Qin Xue,Wei Huang,Guohua Xie
标识
DOI:10.1002/adma.202519387
摘要
Organic light-emitting diodes (OLEDs) have witnessed remarkable advances in both materials science and device engineering over the past three decades. Owing to their intrinsic advantages, including excellent flexibility, low driving voltage, wide viewing angles, broad color gamut, and high electroluminescent efficiency, OLEDs have successfully transitioned from laboratory to commercial applications. The key is the generation and utilization of excitons, which are bound electron-hole pairs formed within organic emitters, which play a decisive role in determining the energy efficiency of OLED-based display and lighting technologies. In particular, triplet excitons generated through charge-transfer processes are particularly important, as they critically influence the electroluminescent performance of state-of-the-art OLED devices. In this review, charge transfer mechanisms operating in organic emitters are systematically discussed and summarized, encompassing both intermolecular and intramolecular interactions, as well as short- and long-range charge-transfer processes in organic emitters. By comparing these different interaction modes, we establish a comprehensive perspective on how charge transfer governs exciton formation and emission behavior. Furthermore, a detailed structure-property relationship is analyzed, offering mechanistic insights that are intended to guide the rational molecular design of next-generation high-performance materials and devices.
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