The light-emitting electrochemical cell promises cost-efficient, large-area emissive applications, as its characteristic in-situ doping enables use of air-stabile electrodes and a solution-processed single-layer active material. However, mutual exclusion of high efficiency and high brightness has proven a seemingly fundamental problem. Here we present a generic approach that overcomes this critical issue, and report on devices equipped with air-stabile electrodes and outcoupling structure that deliver a record-high efficiency of 99.2 cd A(-1) at a bright luminance of 1910 cd m(-2). This device significantly outperforms the corresponding optimized organic light-emitting diode despite the latter employing calcium as the cathode. The key to this achievement is the design of the host-guest active material, in which tailored traps suppress exciton diffusion and quenching in the central recombination zone, allowing efficient triplet emission. Simultaneously, the traps do not significantly hamper electron and hole transport, as essentially all traps in the transport regions are filled by doping.
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机译:发光电化学电池有望实现具有成本效益的大面积发射应用,因为其独特的原位掺杂技术使得能够使用空气稳定的电极和溶液处理的单层活性材料。但是,高效率和高亮度相互排斥已证明是一个看似根本的问题。在这里,我们提出了克服这一关键问题的通用方法,并报告了配备有空气稳定电极和外耦合结构的设备,这些设备在1910 cd m(-)的明亮亮度下提供了创纪录的99.2 cd A(-1)效率。 2)。尽管后者使用钙作为阴极,但该器件的性能明显优于相应的优化有机发光二极管。实现这一目标的关键是主客体活性材料的设计,其中定制的陷阱可抑制激子在中央复合区的扩散和猝灭,从而实现有效的三重态发射。同时,陷阱基本上不会阻碍电子和空穴的传输,因为在传输区域中基本上所有的陷阱都通过掺杂来填充。
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