用于oled的咔唑连接的穿越空间TADF发射器：通过分子结构和激子动力学调谐光物理

IF 4.7 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Advances Pub Date : 2025-08-28 DOI:10.1039/D5MA00731C

Sanyam, Nishi Tejiyan and Anirban Mondal

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引用次数: 0

摘要

热激活延迟荧光（TADF）为高效有机发光二极管（oled）提供了一条有前途的途径，但传统的D-A-D和a - d - a结构往往存在构象灵活性，导致多个单线态激发态和增强的非辐射衰变。这些影响损害了发射效率和颜色纯度。虽然多共振TADF （MR-TADF）系统提供了更好的刚度，但它们的平面结构有利于π -π堆叠，导致聚集诱导猝灭（ACQ）。本研究提出了一种分子设计策略，将咔唑单元集成为刚性的非平面桥，通过破坏平行堆叠来减轻分子内旋转并抑制ACQ。对21个D-A-D和A - d - A型分子进行了计算设计和分析。优化后的结构具有空间分离的前沿轨道，单重态-三重态能隙小（ΔEST），辐射和反向系统间交叉速率快，光致发光量子产率接近统一（PLQYs）。激子动力学模拟进一步证实了有效的TADF行为，而分子动力学轨迹揭示了构象稳定性和通过空间的电荷转移特性。值得注意的是，A1-D3-A1实现了极小的ΔEST （0.001 eV）和最高的kTADF (1.34 × 106 s−1)，能够快速捕获三重态，而D1-A2-D3结合了高振荡器强度和高效的TADF动力学。这些结果表明，细微的结构调整可以产生实质性的性能改进，突出了咔唑桥接TADF发射器是通往稳定、高效OLED材料的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Carbazole-linked through-space TADF emitters for OLEDs: tuning photophysics via molecular architecture and exciton dynamics

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Carbazole-linked through-space TADF emitters for OLEDs: tuning photophysics via molecular architecture and exciton dynamics

Thermally activated delayed fluorescence (TADF) offers a promising route to highly efficient organic light-emitting diodes (OLEDs), yet conventional D–A–D and A–D–A architectures often suffer from conformational flexibility, leading to multiple singlet excited states and enhanced non-radiative decay. These effects compromise both emission efficiency and color purity. While multi-resonant TADF (MR-TADF) systems provide improved rigidity, their planar structures favor π–π stacking, causing aggregation-induced quenching (ACQ). This study presents a molecular design strategy integrating a carbazole unit as a rigid, non-planar bridge to mitigate intramolecular rotation and suppress ACQ by disrupting parallel stacking. A set of 21 such D–A–D and A–D–A type molecules was computationally designed and analyzed. The optimized structures exhibit spatially separated frontier orbitals, resulting in small singlet–triplet energy gaps (ΔE_ST), fast radiative and reverse intersystem crossing rates, and near-unity photoluminescence quantum yields (PLQYs). Exciton dynamics simulations further confirm efficient TADF behavior, while molecular dynamics trajectories reveal conformational stability and through-space charge transfer characteristics. Notably, A1–D3–A1 achieves an exceptionally small ΔE_ST of 0.001 eV and the highest k_TADF of 1.34 × 10⁶ s⁻¹, enabling rapid triplet harvesting, while D1–A2–D3 combines high oscillator strength with efficient TADF dynamics. These results demonstrate that subtle architectural tuning can yield substantial performance improvements, highlighting carbazole-bridged TADF emitters as a pathway toward stable, high-efficiency OLED materials.