材料科学
钙钛矿(结构)
成核
量子效率
光电子学
激子
基质(水族馆)
二极管
结晶
纳米技术
纳米晶
发光二极管
晶体工程
光致发光
薄膜
化学工程
晶界
有机半导体
场效应晶体管
晶体生长
乙腈
有机发光二极管
领域(数学)
半导体
光子学
作者
Guoyi Chen,Zhiqiu Yu,Chaomin Dong,Shuxin Wang,Fangfang Yao,Kailian Dong,Shengjie Du,Zixi Yu,Dexin Pu,Hongsen Cui,Lishuai Huang,Hongyi Fang,Yaxiong Guo,Fang Wang,Jiajun Luo,Jiang Tang,Weijun Ke,Guojia Fang
标识
DOI:10.1002/adma.202522323
摘要
Perovskite light-emitting diodes (PeLEDs) are promising candidates for next-generation display and lighting technologies. However, conventional strategies for controlling morphology and crystalline structure often face challenges such as inefficient carrier transport and poor batch-to-batch reproducibility, primarily due to the presence of long organic ligands and the environment-sensitive nature of crystallization dynamics. Here, we present a localized micro-solvent field engineering strategy that simultaneously enhances device efficiency and reproducibility. By applying a nitrogen micro-gas flow, we obtain a clean nitrogen atmosphere and a lower substrate temperature for subsequent film coating. By incorporating low-boiling-point solvent acetonitrile into the precursor solution as a nucleation promoter, we precisely control the nucleation and growth kinetics. This synergistic approach, which avoids chemical hot-injection synthesis and insulating long-chain ligands, produces uniform quasi-quantum-dot perovskite films with the grain size (7-15 nm) approaching the exciton Bohr diameter with higher exciton binding energy. PeLEDs fabricated using this method demonstrate a peak external quantum efficiency of 33.79%, an average efficiency approaching 31%, excellent batch-to-batch consistency, and successful integration in pixel array devices. This strategy not only overcomes critical limitations in efficiency and reproducibility for solution-processed PeLEDs but also provides a broadly applicable framework to advance the performance and scalability of other perovskite optoelectronic devices.
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