材料科学
聚合物
纳米技术
纳米纤维
光电子学
弹性体
纳米制造
二极管
可伸缩电子设备
发光二极管
量子点
发光
纳米尺度
量子效率
微晶
介观物理学
织物
弯曲
光电效应
有机发光二极管
电致发光
光子学
导电聚合物
作者
Wenkang Shi,Chunyu Hua,Yanyan Cao,Wang Liu,Yudong Liu,Yudong Liu,Jianzhe Sun,Ankang Guo,Mingcong Qin,Cheng-yu Wang,Yangshuang Bian,Wei Wen,Yuxin Liu,Yuxin Liu,Fuyi Wang,Chao Ma,Jianpu Wang,Kai Liu,Jing Hua,Junyu Li
标识
DOI:10.1002/adma.202519650
摘要
Abstract Stretchable polymer light‐emitting diodes (PLEDs) hold promises for skin‐like wearable displays, yet simultaneously achieving high stretchability, efficient luminescence performance, and facile integration remains challenging. Here, a novel strategy introducing microcrystalline elastomer into light‐emitting polymer matrices to fabricate intrinsically stretchable PLEDs that meet all these characteristics is presented. This approach enables the formation of submicron optical self‐gain structures in light‐emitting polymers and the structures confine polymers to form a nanofiber morphology through spatial nanoconfinement effects, which improves polymer crystallinity, facilitates carrier transport, and enhances light outcoupling efficiency through increased reflection and scattering. Leveraging these characteristics, the intrinsically stretchable PLEDs achieved a current efficiency (CE) of 13.70 cd A −1 , an external quantum efficiency (EQE) of 4.70%, a low turn‐on voltage of 3.70 V and a luminance of 32 013 cd m − 2 at 9 V. Additionally, 12 × 12 intrinsically stretchable PLED arrays are fabricated by electrohydrodynamic printing, which exhibit excellent photoelectric stability under tensile and bending strain. This approach holds significant potential for high‐performance stretchable and wearable displays.
科研通智能强力驱动
Strongly Powered by AbleSci AI