Flexible light-emitting diodes with EQE approaching 26.4% from horizontal dipole-oriented metal nanoclusters.
Zhenyu Wang, Yingguo Yang, Guizhong Luo, Wenwu Xu, Chengyu Liu, Tianqi Yang, Wenyu Ji, Fujun Zhang, Min Lu, Yu Zhang, Zhennan Wu, Xue Bai
Abstract
Open AccessMetal nanoclusters, as unique metallic molecules comprising a few to hundreds of metal atoms and stabilized by organic monolayer ligands, have recently emerged as a novel class of chromophores and hold great promise for flexible light-emitting diodes. However, the fabrication of flexible metal nanoclusters-based light-emitting diodes is still hindered by low photoluminescence quantum yields, suboptimal solution processability, and consequently compromised emitter-film quality with random dipole orientations. This work addresses these limitations through strategic molecular engineering by employing 1, 3-di(9H-carbazol-9-yl)benzene as a π-conjugated mediator. This approach enables supramolecular assembly to achieve π-π coupling-mediated horizontal dipole alignment in nanocluster solid films, allowing an external quantum efficiency of up to 26.4% in flexible light-emitting diodes with a maximum brightness of 41,365 cd m-2, and retaining more than 94% of initial efficiency after 2000 bending cycles at 3 mm curvature radius.