TADF for singlet harvesting: next generation OLED materials based on brightly green and blue emitting Cu(I) and Ag(I) compounds

Optics & Photonics - Photonic Devices + Applications Pub Date : 2014-10-08 DOI:10.1117/12.2061010

H. Yersin, Markus J. Leitl, R. Czerwieniec

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引用次数: 24

Abstract

Detailed photophysical studies are presented for Cu2Cl2(dppb)2 and Ag2Cl2(dppb)2. Both compounds show very effective thermally activated delayed fluorescence (TADF) at ambient temperature with an emission quantum yield of the Ag(I) complex of ΦPL(300 K) = 93 %. This emission is blue shifted by 65 nm (2500 cm-1) with respect to the emission of the Cu(I) complex, demonstrating a valuable strategy for engineering blue light emitters. Potentially, these materials are well suited for taking advantage of the singlet harvesting effect in an OLED device. Moreover, both compounds do not show effects of concentration quenching at high emitter concentration, a property which might be attractive for reducing the efficiency roll-off at higher current densities. Investigations down to T = 1.6 K show that spin-orbit coupling (SOC) is particularly weak. This is displayed in the very long emission decay times of the triplet states (T1 states) of metal-toligand charge transfer (3MLCT) character, amounting to τ(Ag2Cl2(dppb)2) = 1.1 ms and τ(Cu2Cl2(dppb)2) = 2.2 ms. According to the TADF mechanism, which leads to the additional decay channel at ambient temperature via the S1 state (of 1MLCT character), an increase of the radiative rate by a factor of 70 and almost 500 for Ag2Cl2(dppb)2 and Cu2Cl2(dppb)2, respectively, is induced. This results in radiative rates at ambient temperature of kr = 6.2 ∙ 104 s-1 (τr = 16 μs, Ag(I) complex) and 11.7 ∙ 104 s-1 (τr = 8.5 μs, Cu(I) complex). Simple approaches are presented that allow us to understand the weakness of SOC on the basis of results from DFT and TD-DFT calculations. Investigations of the emission decay properties down to T = 1.6 K further support the conclusions with respect to the SOC strength.

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用于单线态收获的TADF:基于亮绿色和蓝色发射Cu(I)和Ag(I)化合物的下一代OLED材料

对Cu2Cl2(dppb)2和Ag2Cl2(dppb)2进行了详细的光物理研究。两种化合物在室温下均表现出非常有效的热激活延迟荧光(TADF)， Ag(I)配合物的发射量子产率为ΦPL(300 K) = 93%。相对于Cu(I)配合物的发射，这种发射蓝移了65 nm (2500 cm-1)，展示了一种有价值的工程蓝光发射器策略。潜在地，这些材料非常适合利用OLED器件中的单线态收获效应。此外，这两种化合物在高发射极浓度下都没有表现出浓度猝灭效应，这一特性对于降低高电流密度下的效率滚降可能是有吸引力的。在T = 1.6 K以下的研究表明，自旋轨道耦合(SOC)特别弱。这表现在金属-配体电荷转移(3MLCT)特征的三重态(T1态)的发射衰减时间非常长，τ(Ag2Cl2(dppb)2) = 1.1 ms， τ(Cu2Cl2(dppb)2) = 2.2 ms。根据TADF机制，Ag2Cl2(dppb)2和Cu2Cl2(dppb)2的辐射率分别增加了70倍和近500倍，在室温下通过S1态(1MLCT特征)导致了额外的衰减通道。结果表明，在室温下的辐射率分别为kr = 6.2∙104 s-1 (τr = 16 μs, Ag(I)配合物)和11.7∙104 s-1 (τr = 8.5 μs, Cu(I)配合物)。提出了一些简单的方法，使我们能够根据DFT和TD-DFT计算的结果来理解SOC的弱点。对低至T = 1.6 K的发射衰减特性的研究进一步支持了关于SOC强度的结论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Optics & Photonics - Photonic Devices + Applications

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